EP4371311A1 - Data augmentation for speech enhancement - Google Patents

Data augmentation for speech enhancement

Info

Publication number
EP4371311A1
EP4371311A1 EP22754603.3A EP22754603A EP4371311A1 EP 4371311 A1 EP4371311 A1 EP 4371311A1 EP 22754603 A EP22754603 A EP 22754603A EP 4371311 A1 EP4371311 A1 EP 4371311A1
Authority
EP
European Patent Office
Prior art keywords
audio signal
air
real air
implementations
real
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Pending
Application number
EP22754603.3A
Other languages
German (de)
French (fr)
Inventor
Jia DAI
Kai Li
Xiaoyu Liu
Richard J. CARTWRIGHT
Shaofan YANG
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Dolby Laboratories Licensing Corp
Original Assignee
Dolby Laboratories Licensing Corp
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Dolby Laboratories Licensing Corp filed Critical Dolby Laboratories Licensing Corp
Publication of EP4371311A1 publication Critical patent/EP4371311A1/en
Pending legal-status Critical Current

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Classifications

    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04SSTEREOPHONIC SYSTEMS 
    • H04S7/00Indicating arrangements; Control arrangements, e.g. balance control
    • H04S7/30Control circuits for electronic adaptation of the sound field
    • H04S7/305Electronic adaptation of stereophonic audio signals to reverberation of the listening space
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04RLOUDSPEAKERS, MICROPHONES, GRAMOPHONE PICK-UPS OR LIKE ACOUSTIC ELECTROMECHANICAL TRANSDUCERS; DEAF-AID SETS; PUBLIC ADDRESS SYSTEMS
    • H04R2227/00Details of public address [PA] systems covered by H04R27/00 but not provided for in any of its subgroups
    • H04R2227/007Electronic adaptation of audio signals to reverberation of the listening space for PA

Definitions

  • This disclosure pertains to systems, methods, and media for speech enhancement via attenuating distortion.
  • Audio devices such as headphones, speakers, etc. are widely deployed. People frequently listen to audio content (e.g., podcasts, radio shows, television shows, music videos, user-generated content, short-video, video meetings, teleconferencing meetings, panel discussions, interviews, etc.) that may include distortion, such as reverberation and/or noise. Additionally, audio content may include far-field audio content, such as background noise. Enhancement, such as dereverberation and/or noise suppression may be performed on such audio content. However, enhancement techniques may introduce unwanted perceptual distortions, such as changes in loudness or timbre.
  • audio content e.g., podcasts, radio shows, television shows, music videos, user-generated content, short-video, video meetings, teleconferencing meetings, panel discussions, interviews, etc.
  • audio content may include far-field audio content, such as background noise.
  • Enhancement such as dereverberation and/or noise suppression may be performed on such audio content.
  • enhancement techniques may introduce unwanted perceptual distortions, such as changes in loudness or timbre.
  • the terms “speaker,” “loudspeaker” and “audio reproduction transducer” are used synonymously to denote any sound-emitting transducer (or set of transducers).
  • a typical set of headphones includes two speakers.
  • a speaker may be implemented to include multiple transducers (e.g., a woofer and a tweeter), which may be driven by a single, common speaker feed or multiple speaker feeds.
  • the speaker feed(s) may undergo different processing in different circuitry branches coupled to the different transducers.
  • performing an operation “on” a signal or data e.g., filtering, scaling, transforming, or applying gain to, the signal or data
  • a signal or data e.g., filtering, scaling, transforming, or applying gain to, the signal or data
  • performing the operation directly on the signal or data or on a processed version of the signal or data (e.g., on a version of the signal that has undergone preliminary filtering or pre-processing prior to performance of the operation thereon).
  • system is used in a broad sense to denote a device, system, or subsystem.
  • a subsystem that implements a decoder may be referred to as a decoder system, and a system including such a subsystem (e.g., a system that generates X output signals in response to multiple inputs, in which the subsystem generates M of the inputs and the other X - M inputs are received from an external source) may also be referred to as a decoder system.
  • processor is used in a broad sense to denote a system or device programmable or otherwise configurable (e.g., with software or firmware) to perform operations on data (e.g., audio, or video or other image data).
  • data e.g., audio, or video or other image data.
  • processors include a field-programmable gate array (or other configurable integrated circuit or chip set), a digital signal processor programmed and/or otherwise configured to perform pipelined processing on audio or other sound data, a programmable general purpose processor or computer, and a programmable microprocessor chip or chip set.
  • Some methods may involve obtaining, by a control system a real acoustic impulse response (AIR). Some method may involve identifying, by the control system, a first portion of the real AIR that corresponds to early reflections of a direct sound and a second portion of the real AIR that corresponds to late reflections of the direct sound. Some methods may involve generating, by the control system, one or more synthesized AIRs by modifying the first portion of the real AIR and/or the second portion of the real AIR.
  • AIR real acoustic impulse response
  • Some methods may involve using, by the control system, the real AIR and the one or more synthesized AIRs to generate a plurality of training samples, each training sample comprising an input audio signal and a reverberated audio signal, wherein the reverberated audio signal is generated based at least in part on the input audio signal and one of the real AIR or one of the one or more synthesized AIRs, wherein the plurality of training samples are used to train a machine learning model that takes, as an input, a test audio signal with reverberation and generates, as an output, a dereverberated audio signal.
  • identifying the first portion of the real AIR that corresponds to early reflections and the second portion of the real AIR that corresponds to late reflections comprises selecting a random time value within a predetermined range, wherein the first portion comprises a portion of the real AIR prior to the random time value, and wherein the second portion comprises a portion of the real AIR after the random time value.
  • the predetermined range is from about 20 milliseconds to about 80 milliseconds.
  • modifying the second portion of the real AIR comprises truncating the second portion of the real AIR after a duration of time randomly selected from a predetermined range of late reflection durations.
  • modifying the second portion of the real AIR comprises modifying amplitudes of one or more responses included in the second portion of the real AIR.
  • modifying the amplitudes of the one or more responses included in the second portion of the real AIR comprises: determining a target attenuation function associated with the second portion of the real AIR; and modifying the amplitudes of the one or more responses included in the second portion of the real AIR in accordance with the target attenuation function.
  • the reverberated audio signal is generated by convolving the input audio signal with the one of the real AIR or the one of the one or more synthesized AIRs.
  • methods may further involve adding noise to a convolution of the input audio signal with the one of the real AIR or the one of the one or more synthesized AIRs to generate the reverberated audio signal.
  • methods may further involve generating additional synthesized AIRs by: identifying an updated first portion of the real AIR and an updated second portion of the real AIR; and modifying the updated first portion of the real AIR and/or the updated second portion of the real AIR.
  • methods may further involve providing the plurality of training samples to the machine learning model to generate a trained machine learning model that takes, as the input, the test audio signal with reverberation and generates, as the output, the dereverberated audio signal.
  • the test audio signal is a live-captured audio signal.
  • the real AIR is a measured AIR measured in a physical room.
  • the real AIR is generated using a room acoustics model.
  • the input audio signal is associated with a particular audio content type.
  • the particular audio content type comprises far-field noise.
  • the particular audio content type comprises audio content captured in an indoor environment.
  • methods may further involve obtaining a training set of a plurality of input audio signals each associated with the particular audio content type prior to generating the plurality of training samples.
  • non-transitory media may include memory devices such as those described herein, including but not limited to random access memory (RAM) devices, read-only memory (ROM) devices, etc. Accordingly, some innovative aspects of the subject matter described in this disclosure can be implemented via one or more non-transitory media having software stored thereon.
  • an apparatus may be capable of performing, at least in part, the methods disclosed herein.
  • an apparatus is, or includes, an audio processing system having an interface system and a control system.
  • the control system may include one or more general purpose single- or multi-chip processors, digital signal processors (DSPs), application specific integrated circuits (ASICs), field programmable gate arrays (FPGAs) or other programmable logic devices, discrete gates or transistor logic, discrete hardware components, or combinations thereof.
  • DSPs digital signal processors
  • ASICs application specific integrated circuits
  • FPGAs field programmable gate arrays
  • Figure 1 shows an example of an audio signal in the time domain and in the frequency domain in accordance with some implementations.
  • Figure 2 shows a block diagram of an example system for performing dereverberation of audio signals in accordance with some implementations.
  • Figure 3 shows an example of a process for performing dereverberation of audio signals in accordance with some implementations.
  • Figures 4A and 4B show examples of acoustic impulse responses (AIRs).
  • Figure 5A shows an example of a process for generating synthesized AIRs in accordance with some implementations.
  • Figure 5B shows an example of a process for generating a training set using synthesized AIRs in accordance with some implementations.
  • Figure 6 shows an example architecture of a machine learning model for dereverberating audio signals in accordance with some implementations.
  • Figure 7 shows an example process for training a machine learning model for dereverberating audio signals in accordance with some implementations.
  • Figure 8 shows a block diagram of an example system for performing dereverberation of audio signals in accordance with some implementations.
  • Figure 9 shows a block diagram that illustrates examples of components of an apparatus capable of implementing various aspects of this disclosure.
  • Audio signals may include various types of distortions, such as noise and/or reverberation.
  • reverberation occurs when an audio signal is distorted by various reflections off of various surfaces (e.g., walls, ceilings, floors, furniture, etc.).
  • Reverberation may have a substantial impact on sound quality and speech intelligibility. Accordingly, dereverberation of an audio signal may be performed, for example, to improve speech intelligibility and clarity.
  • Sound arriving at a receiver is made up of direct sound, which includes sound directly from the source without any reflections, and reverberant sound, which includes sound reflected off of various surfaces in the environment.
  • the reverberant sound includes early reflections and late reflections. Early reflections may reach the receiver soon after or concurrently with the direct sound, and may therefore be partially integrated into the direct sound. The integration of early reflections with direct sound creates a spectral coloration effect which contributes to a perceived sound quality.
  • the late reflections arrive at the receiver after the early reflections (e.g., more than 50-80 milliseconds after the direct sound). The late reflections may have a detrimental effect on speech intelligibility. Accordingly, dereverberation may be performed on an audio signal to reduce an effect of late reflections present in the audio signal to thereby improve speech intelligibility.
  • Figure 1 shows an example of a time domain input audio signal 100 and a corresponding spectrogram 102. As illustrated in spectrogram 102, early reflections may produce changes in spectrogram 104 as depicted by spectral colorations 106. Spectrogram 104 also illustrates late reflections 108, which may have a detrimental effect on speech intelligibility.
  • enhancement e.g., dereverberation and/or noise suppression
  • machine learning models such as deep neural networks, may be used to predict a dereverberation mask that, when applied to a reverberated audio signal, generates a dereverberated audio signal.
  • training such machine learning models may be computationally intensive and inefficient.
  • such machine learning models may require a high degree of complexity to be able to achieve some degree of accuracy.
  • such machine learning models may include a vast number of layers, thereby requiring that a corresponding vast number of parameters be optimized.
  • augmented training sets may be generated by generating synthesized acoustic impulse responses (AIRs).
  • AIRs synthesized acoustic impulse responses
  • Augmented training sets may be able to better span potential combinations of room environments, noise, speaker types, etc., that may allow a machine learning model to be trained using a larger and more representative training set, thereby alleviating the problem of model overfitting.
  • a low-complexity machine learning model may be used that utilizes a convolutional neural network (CNN) with a relatively small number of layers (and therefore, a relatively small number of parameters to be optimized) in combination with a recurrent element.
  • CNN convolutional neural network
  • a recurrent element By combining a CNN with a recurrent element in parallel (e.g., as shown in and described below in connection with Figure 6), a low-complexity machine learning model may be trained that generates smooth enhancement masks in a computationally-efficient manner.
  • the recurrent element may inform the CNN portions of audio signals that are to be used in subsequent iterations of training, thereby leading to smoother predicted enhancement masks.
  • recurrent elements examples include a gated recurrent unit (GRU), a long short-term memory (LSTM) network, an Elman recurrent neural network (RNN), and/or any other suitable recurrent element.
  • GRU gated recurrent unit
  • LSTM long short-term memory
  • RNN Elman recurrent neural network
  • a loss function is described herein that allows a machine learning model to both generate a predicted enhanced audio signal that is accurate with respect to the signal of interest in the input distorted audio signal as well as to optimize for minimizing a degree of reverberation in the predicted clean audio signal.
  • such a loss function may incorporate a parameter that approximates a degree of reverberation in a predicted clean audio signal, thereby allowing the machine learning model to be trained based on the ultimate parameter of interest - that is, whether an output signal is substantially dereverberated in comparison to an input signal.
  • an input audio signal can be enhanced using a trained machine learning model.
  • the input audio signal can be transformed to a frequency domain by extracting frequency domain features.
  • a perceptual transformation based on processing by the human cochlea can be applied to the frequency-domain representation to obtain banded features. Examples of a perceptual transformation that may be applied to the frequency -domain representation include a Gammatone filter, an equivalent rectangular bandwidth filter, a transformation based on the Mel scale, or the like.
  • the frequency-domain representation may be provided as an input to a trained machine learning model that generates, as an output, a predicted enhancement mask.
  • the predicted enhancement mask may be a frequency -domain representation of a mask that, when applied to the frequency-domain representation of the input audio signal, generates an enhanced audio signal.
  • an inverse of the perceptual transformation may be applied to the predicted enhancement mask to generate a modified predicted enhancement mask.
  • a frequency-domain representation of the enhanced audio signal may then be generated by multiplying the frequency- domain representation of the input audio signal by the modified predicted enhancement mask.
  • An enhanced audio signal may then be generated by transforming the frequency-domain representation of the enhanced audio signal to the time-domain.
  • a trained machine learning model for enhancing audio signals may be trained to generate, for a given frequency-domain input audio signal, a predicted enhancement mask that, when applied to the frequency -domain input audio signal, generates a frequency-domain representation of a corresponding enhanced audio signal.
  • a predicted enhancement mask may be applied to a frequency -domain representation of the input audio signal by multiplying the frequency-domain representation of the input audio signal and the predicted enhancement mask.
  • the logarithm of the frequency- domain representation of the input audio signal may be taken.
  • a frequency domain representation of the enhanced audio signal may be obtained by subtracting the logarithm of the predicted enhancement mask from the logarithm of the frequency-domain representation of the enhanced audio signal.
  • training a machine learning model may include determining weights associated with one or more nodes and/or connections between nodes of the machine learning model.
  • a machine learning model may be trained on a first device (e.g., a server, a desktop computer, a laptop computer, or the like). Once trained, the weights associated with the trained machine learning model may then be provided (e.g., transmitted to) a second device (e.g., a server, a desktop computer, a laptop computer, a media device, a smart television, a mobile device, a wearable computer, or the like) for use by the second device in dereverberating audio signals.
  • a second device e.g., a server, a desktop computer, a laptop computer, a media device, a smart television, a mobile device, a wearable computer, or the like
  • Figures 2 and 3 show examples of systems and techniques for dereverberating audio signals. It should be noted that although Figures 2 and 3 describe dereverberating audio signals, the systems and techniques described in connection with Figures 2 and 3 may be applied to other types of enhancement, such as noise suppression, a combination of noise suppression and dereverberation, or the like. In other words, rather than generating a predicted dereverberation mask and a predicted dereverberated audio signal, in some implementations, a predicted enhancement mask may be generated, and the predicted enhancement mask may be used to generate a predicted enhanced audio signals, where the predicted enhanced audio signal is a denoised and/or dereverberated version of a distorted input audio signal.
  • a predicted enhancement mask may be generated, and the predicted enhancement mask may be used to generate a predicted enhanced audio signals, where the predicted enhanced audio signal is a denoised and/or dereverberated version of a distorted input audio signal.
  • FIG. 2 shows an example of a system 200 for dereverberating audio signals in accordance with some implementations.
  • a dereverberation audio component 206 takes, as an input, an input audio signal 202, and generates, as an output, a dereverberated audio signal 204.
  • dereverberation audio component 206 includes a feature extractor 208.
  • Feature extractor 208 may generate a frequency-domain representation of input audio signal 202, which may be considered the input signal spectrum.
  • the input signal spectrum may then be provided to a trained machine learning model 210.
  • the trained machine learning model 210 may generate, as an output, a predicted dereverberation mask.
  • the predicted dereverberation mask may be provided to a dereverberated signal spectrum generator 212.
  • Dereverberated signal spectrum generator 212 may apply the predicted dereverberation mask to the input signal spectrum to generate a dereverberated signal spectrum (e.g., a frequency-domain representation of the dereverberated audio signal).
  • the dereverberated signal spectrum may then be provided to a time-domain transformation component 214.
  • Time-domain transformation component 214 may generated dereverberated audio signal 204.
  • Figure 3 shows an example process 300 for dereverberating audio signals in accordance with some implementations.
  • the system shown in and described above in connection with Figure 2 may implement blocks of process 300 to generate dereverberated audio signals.
  • blocks of process 300 may be implemented by a user device, such as a mobile phone, a tablet computer, a laptop computer, a wearable computer (e.g., a smart watch, etc.), a desktop computer, a gaming console, a smart television, or the like.
  • blocks of process 300 may be performed in an order not shown in Figure 3.
  • one or more blocks of process 300 may be omitted.
  • two or more blocks of process 300 may be performed substantially in parallel.
  • Process 300 can begin at 302 by receiving an input audio signal that includes reverberation.
  • the input audio signal may be a bve-captured audio signal, such as live-streamed content, an audio signal corresponding to an in-progress video conference or audio conference, or the like.
  • the input audio signal may be a pre-recorded audio signal, such as an audio signal associated with pre-recorded audio content (e.g., television content, a video, a movie, a podcast, or the like).
  • the input audio signal may be received by a microphone of the user device.
  • the input audio signal may be transmitted to the user device, such as from a server device, another user device, or the like.
  • process 300 can extract features of the input audio signal by generating a frequency-domain representation of the input audio signal.
  • process 300 can generate a frequency-domain representation of the input audio signal using a transform, such as a short-time Fourier transform (STFT), a modified discrete cosine transform (MDCT), or the like.
  • STFT short-time Fourier transform
  • MDCT modified discrete cosine transform
  • the frequency-domain representation of the input audio signal is referred to herein as “binned features” of the input audio signal.
  • the frequency- domain representation of the input audio signal may be modified by applying a perceptually-based transformation that mimics filtering of the human cochlea. Examples of perceptually-based transformations include a Gammatone filter, an equivalent rectangular bandwidth filter, a Mel- scale filter, or the like.
  • the modified frequency -domain transformation is sometimes referred to herein as “banded features” of the input audio signal.
  • process 300 can provide the extracted features (e.g., the frequency -domain representation of the input audio signal or the modified frequency -domain representation of the input audio signal) to a trained machine learning model.
  • the machine learning model may have been trained to generate a dereverberation mask that, when applied to the frequency-domain representation of the input audio signal, generates a frequency -domain representation of a dereverberated audio signal.
  • the logarithm of the extracted features may be provided to the trained machine learning model.
  • the machine learning model may have any suitable architecture or topology.
  • the machine learning model may be or may include a deep neural network, a convolutional neural network (CNN), a long short-term memory (LSTM) network, a recurrent neural network (RNN), or the like.
  • the machine learning model may combine two or more types of networks.
  • the machine learning model may combine a CNN with a recurrent element. Examples of recurrent elements that may be used include a GRU, an LSTM network, an Elman RNN, or the like.
  • An example of a machine learning model architecture that combines a CNN with a GRU is shown in and described below in connection with Figure 6. Note that techniques for training a machine learning model are shown in and described below in connection with Figure 7.
  • process 300 can obtain, from an output of the trained machine learning model, a predicted dereverberation mask that, when applied to the frequency-domain representation of the input audio signal, generates a frequency -domain representation of the dereverberated audio signal.
  • process 300 can modify the predicted dereverberation mask by applying an inverse perceptually-based transformation, such as an inverse Gammatone filter, an inverse equivalent rectangular bandwidth filter, or the like.
  • process 300 can generate a frequency-domain representation of the dereverberated audio signal based on the predicted dereverberation mask generated by the trained machine learning model and the frequency-domain representation of the input audio signal. For example, in some implementations, process 300 can multiply the predicted dereverberation mask by the frequency-domain representation of the input audio signal. In instances in which the logarithm of the frequency-domain representation of the input audio signal was provided to the trained machine learning model, process 300 can generate the frequency-domain representation of the dereverberated audio signal by subtracting the logarithm of the predicted reverberation mask from the logarithm of the frequency -domain representation of the input audio signal.
  • process 300 can then exponentiate the difference of the logarithm of the predicted reverberation mask and the logarithm of the frequency-domain representation of the input audio signal to obtain the frequency-domain representation of the dereverberated audio signal.
  • process 300 can generate a time-domain representation of the dereverberated audio signal.
  • process 300 can generate the time-domain representation of the dereverberated audio signal by applying an inverse transform (e.g., an inverse STFT, an inverse MDCT, or the like) to the frequency-domain representation of the dereverberated audio signal.
  • an inverse transform e.g., an inverse STFT, an inverse MDCT, or the like
  • Process 300 can end at 314.
  • the dereverberated audio signal may be played or presented (e.g., by one or more speaker devices of a user device).
  • the dereverberated audio signal may be stored, such as in local memory of the user device.
  • the dereverberated audio signal may be transmitted, such as to another user device for presentation by the other user device, to a server for storage, or the like.
  • a machine learning model for dereverberating audio signals may be trained using a training set.
  • the training set may include any suitable number of training samples (e.g., 100 training samples, 1000 training samples, 10,000 training samples, or the like), where each training sample includes a clean audio signal (e.g., with no reverberation), and a corresponding reverberated audio signal.
  • the machine learning model may be trained, using the training set, to generate a predicted dereverberation mask that, when applied to a particular reverberated audio signal, generates a predicted dereverberated audio signal.
  • Training a machine learning model that can robustly generate predicted dereverberation masks for different reverberated audio signals may depend on the quality of the training set.
  • the training set may need to capture reverberation from a vast number of different room types (e.g., rooms having different sizes, layouts, furniture, etc.), a vast number of different speakers, etc. Acquiring such a training set is difficult.
  • a training set may be generated by applying various AIRs that each characterize a room reverberation to a clean audio signal, thereby generating pairs of a clean audio signal and a corresponding reverberated audio signal generated by convolving an AIR with the clean audio signal.
  • there may be a limited number of real AIRs available and the real AIRs that are available may not fully characterize potential reverberation effects (e.g., by not adequately capturing rooms of different dimensions, layouts, etc.).
  • real AIRs are used to generate a set of synthesized AIRs.
  • the synthesized AIRs may be generated by altering and/or modifying various characteristics of early reflections and/or late reflections of a measured AIR, as shown in and described below in connection with Figures 4A, 4B, and 5A.
  • a real AIR may be a measured AIR that is measured in a room environment (e.g., using one or more microphones positioned in the room).
  • a real AIR may be a modeled AIR, generated, for example, using a room acoustics model that incorporates room shape, materials in the room, a layout of the room, objects (e.g., furniture) within the room, and/or any combination thereof.
  • a synthesized AIR may be an AIR that is generated based on a real AIR (e.g., by modifying components and/or characteristics of the real AIR), regardless of whether the real AIR is measured or generated using a room acoustics model.
  • a real AIR may be considered a starting point for generating one or more synthesized AIRs.
  • a training sample may include a clean audio signal and a corresponding reverberated audio signal that has been generated by convolving a synthesized AIR with the clean audio signal.
  • the augmented training set may include a larger number of training samples that better capture the extend of potential reverberation effects, thereby leading to a more robust machine learning model when trained with the augmented training set.
  • Figure 4A shows an example of a measured AIR in a reverberant environment.
  • early reflections 402 may arrive at a receiver concurrently or shortly after a direct sound 406.
  • late reflections 404 may arrive at the receiver after early reflections 402.
  • Late reflections 404 are associated with a duration 408, which may be on the order of 100 milliseconds, 0.5 seconds, 1 second, 1.5 seconds, or the like.
  • Late reflections 404 are also associated with a decay 410 that characterizes how an amplitude of late reflections 404 attenuates or decreases over time.
  • decay 410 may be characterized as an exponential decay, a linear function, a portion of a polynomial function, or the like.
  • the boundary between early reflections and late reflections may be within a range of about 50 milliseconds and 80 milliseconds.
  • Figure 4B shows a schematic representation of how the AIR depicted in Figure 4A may be modified to generate a synthesized AIR.
  • a time of a component of early reflections 402 may be modified.
  • a time of early reflection component 456 may be modified in the synthesized AIR, for example, to be earlier or later than a time of the early reflection component in the measured AIR.
  • the duration of the late reflections may be modified. For example, referring to the synthesized AIR depicted in Figure 4B, duration 458 is truncated relative to duration 408 of the corresponding measured AIR.
  • a shape of a decay of the late reflections may be modified in the synthesized AIR.
  • decay 458 is steeper than corresponding decay 408 of the measured AIR, causing late reflection components of the synthesized AIR to be more attenuated relative to the measured AIR.
  • Figure 5A shows an example of a process 500 for generating one or more synthesized AIRs from a single real AIR.
  • blocks of process 500 may be implemented by a device that generates an augmented training set for training of a machine learning model for dereverberating audio signals, such as a server, a desktop computer, a laptop computer, or the like.
  • two or more blocks of process 500 may be performed substantially in parallel.
  • blocks of process 500 may be performed in an order not shown in Figure 5A.
  • one or more blocks of process 500 may be omitted.
  • Process 500 can begin at 502 by obtaining an AIR.
  • the AIR may be a real AIR.
  • the AIR may be measured using a set of microphones within a reverberant room environment.
  • the AIR may be an AIR generated using a room acoustics model.
  • the AIR may be obtained from any suitable source, such as a database that stores measured AIRs, or the like.
  • process 500 can identify a first portion of the AIR that corresponds to early reflections of a direct sound and a second portion of the AIR that corresponds to late reflections of the direct sound.
  • process 500 can identify the first portion and the second portion by identifying a separation boundary between early reflections and late reflections in the AIR.
  • the separation boundary may correspond to a time point in the AIR that divides the AIR into early reflections and late reflections.
  • the separation boundary may be identified by selecting a random value from within a predetermined range. Examples of the predetermined range include 15 milliseconds - 85 milliseconds, 20 milliseconds - 80 milliseconds, 30 milliseconds - 70 milliseconds, or the like.
  • the separation boundary may be a random value selected from any suitable distribution corresponding to the predetermined range (e.g., a uniform distribution, a normal distribution, or the like).
  • process 500 can generate one or more synthesized AIRs by modifying portions of the early reflections and/or the late reflections of the AIR.
  • the early reflections and the late reflections may be identified within the AIR based on the separation boundary identified at block 504.
  • process 500 may generate a synthesized AIR by modifying portions of the early reflections of the AIR. For example, as shown in and described above in connection with Figure 4B, process 500 may modify time points of one or more components of the early reflection. In some implementations, process 500 may modify an order of one or more components of the early reflection.
  • process 500 may modify the order of the one or more components of the early reflection such that the one or more components of the early reflection have different time points within the early reflection part of the AIR.
  • components of the early reflection portion of the AIR may be randomized.
  • process 500 may generate a synthesized AIR by modifying portions of the late reflections of the AIR. For example, as shown in and described above in connection with Figure 4B, process 500 may modify a duration of the late reflections in the synthesized AIR by randomly selecting a time duration after which to truncate the late reflections from a predetermined range.
  • the predetermined range may be determined based on a time point that separates the first portion of the AIR and the second portion of the AIR (e.g., the separation boundary) identified at block 502.
  • the late reflections may be truncated at a randomly selected time duration selected from the range of from the separation boundary to 1 second, from the separation boundary to 1.5 seconds, or the like.
  • process 500 may generate a synthesized AIR by modifying a decay associated with the late reflections.
  • process 500 may generate a decay function (e.g., an exponential decay function, a linear decay, etc.).
  • process 500 may then modify amplitudes of components of the late reflections subject to the generated decay function. In some implementations, this may cause the synthesized AIR to have late reflection components that are attenuated relative to the corresponding late reflection components of the measured AIR. Conversely, in some implementations, this may cause the synthesized AIR to have late reflection components that are amplified or boosted relative to the corresponding late reflection components of the measured AIR.
  • Modification of the decay associated with the late reflections may change a reverberation time (RT), such as the time for reverberation to decrease by 60 dB (e.g., the RT60).
  • RT reverberation time
  • a synthesized AIR may include modifications to both the early reflection components and the late reflection components.
  • early reflection components and/or late reflection components may be modified in multiple ways in a synthesized AIR relative to the real AIR.
  • a synthesized AIR may include late reflections that have both been truncated and late reflection components that have been modified in amplitude based at least in part on a modified decay applied to the late reflections of the synthesized AIR.
  • the synthesized AIR may be further modified, e.g., in post-processing.
  • a direct-to-reverberant ratio (DRR) associated with the synthesized AIR may be modified.
  • the DRR associated with the synthesized AIR may be modified by applying a gain to a portion (e.g., an early reflection portion of the synthesized AIR) to increase or decrease the DRR.
  • multiple modified synthesized AIRs may be generated from a single synthesized AIR.
  • multiple modified synthesized AIRs may be generated by applying different gains, each corresponding to a different modified synthesized AIR, to the single synthesized AIR.
  • process 500 can determine whether additional synthesized AIRs are to be generated based on the AIR obtained at block 502. In some implementations, process 500 can determine whether additional synthesized AIRs are to be generated based on whether a target or threshold number of synthesized AIRs that are to be generated from the AIR have been generated. For example, in an instance in which N synthesized AIRs are to be generated from a particular AIR, process 500 can determined whether N synthesized AIRs have been generated from the AIR obtained at block 502. It should be noted that N may be any suitable value, such as 1, 5, 10, 20, 50, 100, 500, 1000, 2000, etc.
  • process 500 determines that additional synthesized AIRs are not to be generated (“no” at block 508), process 500 can end at 510. Conversely, if, at block 508, process 500 determines that additional synthesized AIRs are to be generated (“yes” at block 508), process 500 can loop back to block 504 and can identify a different first portion of the AIR and second portion of the AIR obtained at block 502. By looping through blocks 504-508, process 500 may generate multiple synthesized AIRs from a single measured AIR.
  • Figure 5B shows an example of a process 550 for generating an augmented training set using real and/or synthesized AIRs.
  • the augmented training set may be used for training a machine learning model for dereverberating audio signals.
  • blocks of process 550 may be implemented by a device suitable for generating an augmented training set, such as a server, a desktop computer, a laptop computer, or the like.
  • the device may be the same as the device that implemented blocks of process 500, as shown in and described above in connection with Figure 5A.
  • two or more blocks of process 550 may be performed substantially in parallel.
  • blocks of process 550 may be performed in an order other than what is shown in Figure 5B.
  • one or more blocks of process 550 may be omitted.
  • Process 550 can begin at 552 by obtaining a set of clean input audio signals (e.g., input audio signals without any reverberation and/or noise).
  • the clean input audio signals in the set of clean input audio signals may have been recorded by any suitable number of devices (or microphones associated with any suitable number of devices).
  • two or more of the clean input audio signals may have been recorded by the same device.
  • each of the clean input audio signals may have been recorded by a different device.
  • two or more of the clean input audio signals may have been recorded in the same room environment.
  • each of the clean input audio signals may have been recorded in a different room environment.
  • a clean input audio signal in the set of clean input audio signals may include any combination of types of audible sounds, such as speech, music, sound effects, or the like.
  • each clean input audio signal may be devoid of reverberation, echo, and/or noise.
  • process 550 can obtain a set of AIRs that include real AIRs and/or synthesized AIRs.
  • the set of AIRs may include any suitable number of AIRs (e.g., 100 AIRs, 200 AIRs, 500 AIRs, or the like).
  • the set of AIRs may include any suitable ratio of real AIRs to synthesized AIRs, such as 90% synthesized AIRs and 10% real AIRs, 80% synthesized AIRs and 20% real AIRs, or the like. More detailed techniques for generating synthesized AIRs are shown in and described above in connection with Figure 5A.
  • process 550 can, for each pairwise combination of clean input audio signal in the set of clean input audio signals and AIR in the set of AIRs, generate a reverberated audio signal based on the clean input audio signal and the AIR. For example, in some implementations, process 550 can convolve the AIR with the clean input audio signal to generate the reverberated audio signal. In some implementations, given N clean input audio signals and M AIRs, process 550 can generate up to N x M reverberated audio signals.
  • process 550 can, for one or more of the reverberated audio signals generated at block 556, add noise to generate a noisy reverberated audio signal.
  • noise examples include white noise, pink noise, brown noise, multi talker speech babble, or the like.
  • Process 550 may add different types of noise to different reverberated audio signals. For example, in some implementations, process 550 may add white noise to a first reverberated audio signal to generate a first noisy reverberated audio signal. Continuing with this example, in some implementations, process 550 may add multi-talker speech babble type noise to the first reverberated audio signal to generate a second noisy reverberated audio signal.
  • process 550 may add brown noise to a second reverberated audio signal to generate a third noisy reverberated audio signal.
  • different versions of a noisy reverberated audio signal may generated by adding different types of noise to a reverberated audio signal.
  • block 558 may be omitted, and the training set may be generated without adding noise to any reverberated audio signals.
  • process 550 has generated a training set comprising multiple training samples.
  • Each training sample may include a clean audio signal and a corresponding reverberated audio signal.
  • the reverberated audio signal may or may not include added noise.
  • a single clean audio signal may be associated with multiple training samples.
  • a clean audio signal may be used to generate multiple reverberated audio signals by convolving the clean audio signal with multiple different AIRs.
  • a single reverberated audio signal (e.g., generated by convolving a single clean audio signal with a single AIR) may be used to generated multiple noisy reverberated audio signals, each corresponding to a different type of noise added to the single reverberated audio signal.
  • a single clean audio signal may be associated with 10, 20, 30, 100, or the like training samples, each comprising a different corresponding reverberated audio signal (or noisy reverberated audio signal).
  • an augmented training set may be generated for a particular type of audio content.
  • the particular type of audio content may correspond to a type of audio content for which dereverberation may be particularly difficult.
  • it may be difficult to perform dereverberation on audio signals that include far-field noise such as the noise of a dog barking or a baby crying in the background of an audio signal that includes near- field speech (e.g., from a video conference, from an audio call, or the like). Difficulty in performing dereverberation on far-field noise may lead to poor noise management (e.g., denoising of the audio signal).
  • a training dataset used to train such a model may not have enough training samples of the particular type of far-field noise present in an expansive set of room acoustics, thereby making the model trained with such a limited training set less robust. Accordingly, generating an augmented training set for a particular type of audio content may allow for a more robust model to be trained.
  • the particular type of audio content may include particular types of sounds or events (e.g., a dog barking, a baby crying, an emergency siren passing by, or the like) and/or particular audio environments (e.g., an indoor environment, an outdoor environment, an indoor shared workspace, or the like).
  • the augmented training set may be generated by first identifying a training set of audio signals that include the particular type of audio content. For example, a training set that includes dogs barking in the background of near-field speech may be obtained. As another example, a training set that includes a far-field siren passing by in the background of near-field speech may be obtained.
  • a training set that includes audio content captured in indoor environments may be obtained.
  • the training set may be obtained by applying audio signals from a corpus of audio signals that classifies each audio signals as associated with the particular type of audio content.
  • the augmented training set may be generated by applying synthesized AIRs and/or noise of a particular type (e.g., speech noise, indoor room noise, etc.) to the identified training set to generate the augmented training set.
  • an augmented training set may be used for training speech enhancement models other than dereverberation models.
  • such an augmented training set may be used to train machine learning models for noise management (e.g., denoising), machine learning models that perform a combination of noise management and dereverberation, or the like.
  • a machine learning model for dereverberating audio signals may have various types of architectures.
  • the machine learning model may take, as an input, a frequency-domain representation of a reverberated audio signal and produce, as an output, a predicted dereverberation mask that, when applied to the frequency-domain representation of the reverberated audio signal, generates a frequency -domain representation of a dereverberated (e.g., clean) audio signal.
  • Example architecture types include a CNN, an LSTM, an RNN, a deep neural network, or the like.
  • a machine learning model may combine two or more architecture types, such as a CNN and a recurrent element.
  • a CNN may be used to extract features of an input reverberated audio signal at different resolutions.
  • a recurrent element may serve as a memory gate that controls an amount of previously provided input data that is used by the CNN.
  • Use of a recurrent element in combination with a CNN may allow the machine learning model to produce smoother outputs. Additionally, use of a recurrent element in combination with a CNN may allow the machine learning model to achieve a higher accuracy and with a decreased training time. Accordingly, use of a recurrent element in combination with a CNN may improve computational efficiency by decreasing time and/or computational resources used to train a robust, accurate machine learning model for dereverberating audio signals.
  • types of recurrent elements that may be used include a GRU, an LSTM network, an Elman RNN, and/or any other suitable type of recurrent element or architecture.
  • a recurrent element may be combined with a CNN such that the recurrent element and the CNN are in parallel.
  • outputs of the recurrent element may be provided to one or more layers of the CNN such that the CNN generates an output based on outputs of layers of the CNN and based on an output of the recurrent element.
  • a CNN utilized in a machine learning model may include multiple layers. Each layer may extract features of an input reverberated audio signal spectrum (e.g., a frequency-domain representation of the reverberated audio signal) at different resolutions.
  • layers of the CNN may have different dilation factors. Use of dilation factors greater than 1 may effectively increase the receptive field of a convolution filter used for a particular layer having a dilation factor greater than 1 but without increasing the number of parameters. Use of dilation factors greater than 1 may therefore allow a machine learning model to be more robustly trained (by increasing receptive field size) while not increasing in complexity (e.g., by maintaining a number of parameters to be learned or optimized).
  • a CNN may have a first group of layers, each having an increasing dilation rate, and a second group of layers, each having a decreasing dilation rate.
  • the first group of layers may include 6 layers, having dilation factors of 1, 2, 4, 8, 12, and 20, respectively.
  • the second group of layers may include 5 layers decreasing in dilation factor (e.g., 5 layers having dilation factors of 12, 8, 4, 2, and 1, respectively).
  • the size of the receptive field considered by the CNN is related to the dilation factors, the convolution filter size, a stride size, and/or a pad size (e.g., whether or not the model is causal).
  • the CNN may have a total receptive field of (2x(l+2+4+8+12+20))+l frames, or 95 frames.
  • the total receptive field may correspond to a delay line duration that indicates a duration of the spectrum that is considered by the machine learning model. It should be noted that the dilation factors described above are merely exemplary. In some implementations, smaller dilation factors may be used to, for example, decrease a delay duration for real-time audio signal duration.
  • the machine learning model may be zero latency. In other words, the machine learning model may not use look ahead, or future data points. This is sometimes referred to as the machine learning model being causal. Conversely, in some implementations, the machine learning model may implement layers that utilize look ahead blocks.
  • FIG. 6 shows an example of a machine learning model 600 that combines a CNN 606 and a GRU 608 in parallel.
  • machine learning model 600 takes, as an input 602, a reverberated audio signal spectrum (e.g., a frequency -domain representation of the reverberated audio signal) and generates an output 604 corresponding to a predicted dereverberation mask.
  • a reverberated audio signal spectrum e.g., a frequency -domain representation of the reverberated audio signal
  • CNN 606 includes a first set of layers 610 that have increasing dilation factors.
  • first set of layer 610 includes 6 layers with dilation factors of 1, 2, 4, 8, 12, and 20, respectively.
  • First set of layers 610 is followed by a second set of layers 612 that have decreasing dilation factors.
  • second set of layers 612 includes 5 layers with dilation factors of 12, 8, 4, 2, and 1.
  • Second set of layers 612 is followed by a third set of layers 614, which each have a dilation factor of 1.
  • first set of layers 610, second set of layers 612, and third set of layers 614 may each include convolutional blocks. Each convolutional block may utilize a convolutional filter.
  • CNN 606 utilizes convolutional filters of a 3x3 size, this is merely exemplary, and, in some implementations, other filter sizes (e.g., 4x4, 5x5, or the like) may be used.
  • each layer of CNN 606 may feed forward to a next, or subsequent layer of CNN 606.
  • an output of a layer with a particular dilation factor may be provided as an input to a second layer having the same dilation factor.
  • a layer of first set of layers 610 having a dilation factor of 2 may be provided via a connection 614 to a layer of second set of layers 612 having a dilation factor of 2.
  • Connections 616, 618, and 620 similarly provide connections between layers having the same dilation factors.
  • an output of GRU 608 may be provided to various layers of CNN 606 such that CNN 606 generates output 604 based on the layers of CNN 606 as well as the output of GRU 608.
  • GRU 608 may provide an output to layers having decreasing dilation factors (e.g., to layers included in second set of layers 612) via connections 622, 624, 626, 628, 630, and 632.
  • GRU 608 may have any suitable number of nodes (e.g., 48, 56, 64, or the like) and/or any suitable number of layers (e.g., 1, 2, 3, 4, 8, or the like).
  • GRU 608 may be preceded by a first reshape block 634 which reshapes dimensions of input 602 to dimensions suitable for and/or required by GRU 608.
  • a second reshape block 636 may follow GRU 608.
  • Second reshape block 636 may reshape dimensions of an output generated by GRU 608 to dimensions suitable for provision to each layer of CNN 606 that receives the output of GRU 608.
  • a machine learning model may be trained using a loss function that indicates a degree of reverberation associated with a predicted dereverberated audio signal generated using a predicted dereverberation mask generated by the machine learning model.
  • the machine learning model may not only generate dereverberated audio signals similar in content to the corresponding reverberated audio signals (e.g., including similar direct sound content as in the reverberated audio signal), but additionally, generate dereverberated audio signals with less reverberation.
  • a loss term for a particular training sample, may be a combination of a difference between a predicted dereverberated audio signal and a ground-truth clean audio signal and a degree of reverberation associated with the predicted dereverberated audio signal.
  • a degree of reverberation included in a loss function may be a speech-to-reverberation modulation energy.
  • the speech-to- reverberation modulation energy may be a ratio of modulation energy at relatively high modulation frequencies relative to modulation energy over all modulation frequencies.
  • the speech-to-reverberation modulation energy may be a ratio of modulation energy at relatively high modulation frequencies relative to modulation energy over relatively low modulation frequencies.
  • relatively high modulation frequencies and relatively low modulation frequencies may be identified based on modulation filters. For example, in an instance in which modulation energy is determined at M modulation frequency bands, the highest N of the M (e.g., 3, 4, 5, etc.) modulation frequency bands may be considered as corresponding to “high modulation frequencies,” and the remaining bands (e.g., M-N) may be considered as corresponding to “low modulation frequencies.”
  • Figure 7 shows an example of a process 700 for training a machine learning model using a loss function that incorporates a degree of reverberation of a predicted dereverberated audio signal in accordance with some implementations.
  • blocks of process 700 may be implemented by a device, such as a server, a desktop computer, a laptop computer, or the like.
  • a device that implements blocks of process 700 may be the same device or a different device as that used to construct the augmented training set.
  • two or more blocks of process 700 may be executed substantially in parallel.
  • blocks of process 700 may be performed in an order other than what is shown in Figure 7.
  • one or more blocks of process 700 may be omitted.
  • Process 700 can begin at 702 by obtaining a training set that includes training samples that comprise pairs of reverberated audio signals and clean audio signals.
  • the clean audio signals may be considered “ground-truth” signals that the machine learning model is to be trained to predict, or generate.
  • the training set may be an augmented training set that has been constructed using synthesized AIRs, as described above in connection with Figures 4A, 4B, 5A, and 5B.
  • process 700 may obtain the training set from a database, a remote server, or the like.
  • process 700 can provide the reverberated audio signal to a machine learning model to obtain a predicted dereverberation mask.
  • process 700 may provide the reverberated audio signal by determining a frequency-domain representation of the reverberated audio signal and providing the frequency-domain representation of the reverberated audio signal.
  • the frequency-domain representation of the reverberated audio signal may have been filtered or otherwise transformed using a filter that approximates filtering of the human cochlea, as shown in and described above in connection with block 304 of Figure 3.
  • the machine learning model may have any suitable architecture.
  • the machine learning model may include a deep neural network, a CNN, an LSTM, an RNN, or the like.
  • the machine learning model may combine two or more architectures, such as a CNN and a recurrent element.
  • a CNN may use dilation factors at different layers.
  • a specific example of a machine learning model that may be used is shown in and described above in connection with Figure 6.
  • process 700 can obtain a predicted dereverberated audio signal using the predicted dereverberation mask. For example, in some implementations, process 700 can apply the predicted dereverberation mask to the frequency-domain representation of the reverberated audio signal to obtain a frequency-domain representation of the dereverberated audio signal, as shown in and described above in connection with block 310 of Figure 3. Continuing with this example, in some implementations, process 700 can then generate a time-domain representation of the dereverberated audio signal, as shown in and described above in connection with block 312 of Figure 3.
  • process 700 can determine a value of a reverberation metric associated with the predicted dereverberated audio signal.
  • the reverberation metric may be a speech-to-reverberation modulation energy (generally denoted herein as fsrmAz), where z is the predicted dereverberated audio signal) of one or more frames of the predicted dereverberated audio signal.
  • Zj,k represents the average modulation energy over frames of the 7 th critical band grouped by the k lb modulation filter, where there are 23 critical bands and 8 modulation bands. Higher values of fsrmr(z ) are indicative of a higher degree of reverberation. It should be noted that other numbers of critical bands and/or modulation bands may be used to determine the speech-to-reverberation modulation energy.
  • process 700 can determine a loss term based on the clean audio signal, the predicted dereverberated audio signal, and the value of the reverberation metric.
  • the loss term may be a combination of a difference between the clean audio signal and the predicted dereverberated audio signal and the value of the reverberation metric.
  • the combination may be a weighted sum, where the value of the reverberation metric is weighted by an importance of minimizing reverberation in outputs produced using the machine learning model.
  • An example equation of the loss term for a particular predicted dereverberated audio signal (denoted herein as y We ) and a particular clean audio signal (denoted herein as y re j) is given by:
  • the loss term may be increased in instances in which there is a relatively high degree of reverberation in the predicted clean audio signal and/or in which the predicted dereverberated audio signal differs substantially from the ground-truth clean audio signal.
  • process 700 can update weights of the machine learning model based at least in part on the loss term. For example, in some implementations, process 700 may use gradient descent and/or any other suitable technique to calculate updated weight values associated with the machine learning model. The weights may be updated based on other factors, such as a learning rate, a dropout rate, etc. The weights may be associated with various nodes, layers, etc., of the machine learning model.
  • process 700 can determine whether the machine learning model is to continue being trained.
  • Process 700 can determine whether the machine learning model is to continue being trained based on a determination of whether a stopping criteria has been reached.
  • the stopping criteria may include a determination that an error associated with the machine learning model has decreased below a predetermined error threshold, that weights associated with the machine learning model are being changed from one iteration to a next by less than a predetermined change threshold, and/or the like.
  • process 700 determines that the machine learning model is not to continue being trained (“no” at block 714)
  • process 700 can end at 716.
  • process 700 determines that the machine learning model is to continue being trained (“yes” at block 714)
  • process 700 can loop back to 704 and can loop through blocks 704-714 with a different training sample.
  • an augmented training set (e.g., as described above in connection with Figures 4A, 4B, 5A, and 5B) may be used in connection with a machine learning model that utilizes a loss function that incorporates a degree of reverberation of a predicted clean audio signal, as described above in connection with Figure 7.
  • the machine learning model may have an architecture that incorporates a CNN and a GRU in parallel, as shown in and described above in connection with Figure 6.
  • FIG. 8 shows a schematic diagram of an example system 800 that utilizes an augmented training set in connection with a machine learning model that utilizes a loss function that incorporates a degree of reverberation metric.
  • system 800 includes a training set creation component 802.
  • Training set creation component 802 may generate an augmented training set that may be used by a machine learning model for dereverberating audio signals.
  • training set component 802 may be implemented, for example, on a device that generates and/or stores an augmented training set.
  • Training set creation component 802 may retrieve measured AIRs from an AIR database 806.
  • Training set creation component 802 may then generate synthesized AIRs based on the measured AIRs retrieved from AIR database 806. More detailed techniques for generating synthesized AIRs are shown in and described above in connection with Figures 4A, 4B, and 5A.
  • Training set creation component 802 can retrieve clean audio signals from clean audio signals database 804.
  • Training set creation component 802 can then generate an augmented training set 808 based on the measured AIRs, the synthesized AIRs, and the clean audio signals. More detailed techniques for generating an augmented training set are shown in and described above in connection with Figure 5B.
  • Augmented training set 808 may include multiple (e.g., one hundred, one thousand, ten thousand, or the like) training samples, with each training sample being a pair of a clean audio signal (e.g., retrieved from clean audio signal database 804) and a corresponding reverberated audio signal generated by training set creation component 802 based on a single AIR (either a measured AIR or a synthesized AIR).
  • Augmented training set 808 may then be used to train a machine learning model 810a.
  • machine learning model 810a may have an architecture that includes a CNN and a recurrent element (e.g., a GRU, an LSTM network, an Elman RNN, or the like) in parallel.
  • the CNN may generate an output based on outputs of layers of the CNN as well as an output of the recurrent element.
  • An example of such an architecture is shown in and described above in connection with Figure 6.
  • Machine learning model 810a may include a prediction component 812a and a reverberation determination component 814.
  • Prediction component 812a may generate, for a reverberated audio signal obtained from augmented training set 808, a predicted dereverberated audio signal. Examples for generating the predicted dereverberated audio signal are described above in more detail in connection with Figures 2, 3, and 7.
  • Reverberation determination component 814 may determine a degree of reverberation in the predicted dereverberated audio signal. For example, the degree of reverberation may be based on a speech-to-reverberation modulation energy, as described above in connection with block 708 of Figure 7. The degree of reverberation may be used to update weights associated with prediction component 812a. For example, the degree of reverberation may be included in a loss function that is minimized or optimized to update weights associated with prediction component 812a, as shown in and described above in connection with blocks 710 and 712 of Figure 7.
  • trained machine learning model 810b may utilize trained prediction component 812b (e.g., corresponding to finalized weights) to generate dereverberated audio signals.
  • trained machine learning model 810b may take, as an input, a reverberated audio signal 814, and may generate, as an output, a dereverberated audio signal 816.
  • trained machine learning model 810b may have the same architecture as machine learning model 810a, but may not determine a degree of reverberation at inference time.
  • Figure 9 is a block diagram that shows examples of components of an apparatus capable of implementing various aspects of this disclosure. As with other figures provided herein, the types and numbers of elements shown in Figure 9 are merely provided by way of example. Other implementations may include more, fewer and/or different types and numbers of elements. According to some examples, the apparatus 900 may be configured for performing at least some of the methods disclosed herein. In some implementations, the apparatus 900 may be, or may include, a television, one or more components of an audio system, a mobile device (such as a cellular telephone), a laptop computer, a tablet device, a smart speaker, or another type of device.
  • a mobile device such as a cellular telephone
  • the apparatus 900 may be, or may include, a server.
  • the apparatus 900 may be, or may include, an encoder.
  • the apparatus 900 may be a device that is configured for use within an audio environment, such as a home audio environment, whereas in other instances the apparatus 900 may be a device that is configured for use in “the cloud,” e.g., a server.
  • the apparatus 900 includes an interface system 905 and a control system 910.
  • the interface system 905 may, in some implementations, be configured for communication with one or more other devices of an audio environment.
  • the audio environment may, in some examples, be a home audio environment. In other examples, the audio environment may be another type of environment, such as an office environment, an automobile environment, a train environment, a street or sidewalk environment, a park environment, etc.
  • the interface system 905 may, in some implementations, be configured for exchanging control information and associated data with audio devices of the audio environment.
  • the control information and associated data may, in some examples, pertain to one or more software applications that the apparatus 900 is executing.
  • the interface system 905 may, in some implementations, be configured for receiving, or for providing, a content stream.
  • the content stream may include audio data.
  • the audio data may include, but may not be limited to, audio signals.
  • the audio data may include spatial data, such as channel data and/or spatial metadata.
  • the content stream may include video data and audio data corresponding to the video data.
  • the interface system 905 may include one or more network interfaces and/or one or more external device interfaces (such as one or more universal serial bus (USB) interfaces).
  • USB universal serial bus
  • the interface system 905 may include one or more wireless interfaces.
  • the interface system 905 may include one or more devices for implementing a user interface, such as one or more microphones, one or more speakers, a display system, a touch sensor system and/or a gesture sensor system.
  • the interface system 905 may include one or more interfaces between the control system 910 and a memory system, such as the optional memory system 915 shown in Figure 9.
  • the control system 910 may include a memory system in some instances.
  • the interface system 905 may, in some implementations, be configured for receiving input from one or more microphones in an environment.
  • the control system 910 may, for example, include a general purpose single- or multi chip processor, a digital signal processor (DSP), an application specific integrated circuit (ASIC), a field programmable gate array (FPGA) or other programmable logic device, discrete gate or transistor logic, and/or discrete hardware components.
  • DSP digital signal processor
  • ASIC application specific integrated circuit
  • FPGA field programmable gate array
  • control system 910 may reside in more than one device.
  • a portion of the control system 910 may reside in a device within one of the environments depicted herein and another portion of the control system 910 may reside in a device that is outside the environment, such as a server, a mobile device (e.g., a smartphone or a tablet computer), etc.
  • a portion of the control system 910 may reside in a device within one environment and another portion of the control system 910 may reside in one or more other devices of the environment.
  • control system 910 may reside in a device that is implementing a cloud-based service, such as a server, and another portion of the control system 910 may reside in another device that is implementing the cloud- based service, such as another server, a memory device, etc.
  • the interface system 905 also may, in some examples, reside in more than one device.
  • control system 910 may be configured for performing, at least in part, the methods disclosed herein. According to some examples, the control system 910 may be configured for implementing methods of dereverberating audio signals, training a machine learning model that performs dereverberation of audio signals, generating a training set for a machine learning model that performs dereverberation of audio signals, generating synthesized AIRs for inclusion in a training set, or the like. [0109] Some or all of the methods described herein may be performed by one or more devices according to instructions (e.g., software) stored on one or more non-transitory media.
  • instructions e.g., software
  • non-transitory media may include memory devices such as those described herein, including but not limited to random access memory (RAM) devices, read-only memory (ROM) devices, etc.
  • the one or more non-transitory media may, for example, reside in the optional memory system 915 shown in Figure 9 and/or in the control system 910. Accordingly, various innovative aspects of the subject matter described in this disclosure can be implemented in one or more non-transitory media having software stored thereon.
  • the software may, for example, include instructions for dereverberating audio signals using a trained machine learning model, training a machine learning model that performs dereverberation of audio signals, generating one or more synthesized AIRs, generating a training set for training a machine learning model that performs dereverberation of audio signals, etc.
  • the software may, for example, be executable by one or more components of a control system such as the control system 910 of Figure 9.
  • the apparatus 900 may include the optional microphone system 920 shown in Figure 9.
  • the optional microphone system 920 may include one or more microphones.
  • one or more of the microphones may be part of, or associated with, another device, such as a speaker of the speaker system, a smart audio device, etc.
  • the apparatus 900 may not include a microphone system 920.
  • the apparatus 900 may nonetheless be configured to receive microphone data for one or more microphones in an audio environment via the interface system 910.
  • a cloud-based implementation of the apparatus 900 may be configured to receive microphone data, or a noise metric corresponding at least in part to the microphone data, from one or more microphones in an audio environment via the interface system 910.
  • the apparatus 900 may include the optional loudspeaker system 925 shown in Figure 9.
  • the optional loudspeaker system 925 may include one or more loudspeakers, which also may be referred to herein as “speakers” or, more generally, as “audio reproduction transducers.”
  • the apparatus 900 may not include a loudspeaker system 925.
  • the apparatus 900 may include headphones. Headphones may be connected or coupled to the apparatus 900 via a headphone jack or via a wireless connection (e.g., BLUETOOTH).
  • Some aspects of present disclosure include a system or device configured (e.g., programmed) to perform one or more examples of the disclosed methods, and a tangible computer readable medium (e.g., a disc) which stores code for implementing one or more examples of the disclosed methods or steps thereof.
  • a tangible computer readable medium e.g., a disc
  • some disclosed systems can be or include a programmable general purpose processor, digital signal processor, or microprocessor, programmed with software or firmware and/or otherwise configured to perform any of a variety of operations on data, including an embodiment of disclosed methods or steps thereof.
  • Such a general purpose processor may be or include a computer system including an input device, a memory, and a processing subsystem that is programmed (and/or otherwise configured) to perform one or more examples of the disclosed methods (or steps thereof) in response to data asserted thereto.
  • Some embodiments may be implemented as a configurable (e.g., programmable) digital signal processor (DSP) that is configured (e.g., programmed and otherwise configured) to perform required processing on audio signal(s), including performance of one or more examples of the disclosed methods.
  • DSP digital signal processor
  • embodiments of the disclosed systems may be implemented as a general purpose processor (e.g., a personal computer (PC) or other computer system or microprocessor, which may include an input device and a memory) which is programmed with software or firmware and/or otherwise configured to perform any of a variety of operations including one or more examples of the disclosed methods.
  • PC personal computer
  • microprocessor which may include an input device and a memory
  • elements of some embodiments of the inventive system are implemented as a general purpose processor or DSP configured (e.g., programmed) to perform one or more examples of the disclosed methods, and the system also includes other elements (e.g., one or more loudspeakers and/or one or more microphones).
  • a general purpose processor configured to perform one or more examples of the disclosed methods may be coupled to an input device (e.g., a mouse and/or a keyboard), a memory, and a display device.
  • Another aspect of present disclosure is a computer readable medium (for example, a disc or other tangible storage medium) which stores code for performing (e.g., coder executable to perform) one or more examples of the disclosed methods or steps thereof.
  • code for performing e.g., coder executable to perform

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  • Engineering & Computer Science (AREA)
  • Multimedia (AREA)
  • Physics & Mathematics (AREA)
  • Acoustics & Sound (AREA)
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  • Stereophonic System (AREA)
  • Reverberation, Karaoke And Other Acoustics (AREA)

Abstract

A method for dereverberating audio signals is provided. In some implementations, the method involves obtaining a real acoustic impulse response (AIR); identifying a first portion of the real AIR corresponding to early reflections of a direct sound and a second portion of the real AIR that corresponding to late reflections of the direct sound; generating one or more synthesized AIRs by modifying the first portion of the real AIR and/or the second portion of the real AIR; and using the real AIR and the one or more synthesized AIRs to generate a plurality of training samples, each training sample comprising an input audio signal and a reverberated audio signal, wherein the reverberated audio signal is generated based on the input audio signal and one of the real AIR or one of the one or more synthesized AIRs, which plurality of training samples are used to train a machine learning model.

Description

DATA AUGMENTATION FOR SPEECH ENHANCEMENT
CROSS-REFERENCE TO RELATED APPLICATIONS
[0001] This application claims the priority benefit of U.S. Provisional Application No. 63/260,201, filed on August 12, 2021 and International Application No. PCT/CN2021/106536, filed on July 15, 2021, the contents of which are hereby incorporated in its entirety.
TECHNICAL FIELD
[0002] This disclosure pertains to systems, methods, and media for speech enhancement via attenuating distortion.
BACKGROUND
[0003] Audio devices, such as headphones, speakers, etc. are widely deployed. People frequently listen to audio content (e.g., podcasts, radio shows, television shows, music videos, user-generated content, short-video, video meetings, teleconferencing meetings, panel discussions, interviews, etc.) that may include distortion, such as reverberation and/or noise. Additionally, audio content may include far-field audio content, such as background noise. Enhancement, such as dereverberation and/or noise suppression may be performed on such audio content. However, enhancement techniques may introduce unwanted perceptual distortions, such as changes in loudness or timbre.
NOTATION AND NOMENCLATURE
[0004] Throughout this disclosure, including in the claims, the terms “speaker,” “loudspeaker” and “audio reproduction transducer” are used synonymously to denote any sound-emitting transducer (or set of transducers). A typical set of headphones includes two speakers. A speaker may be implemented to include multiple transducers (e.g., a woofer and a tweeter), which may be driven by a single, common speaker feed or multiple speaker feeds. In some examples, the speaker feed(s) may undergo different processing in different circuitry branches coupled to the different transducers. [0005] Throughout this disclosure, including in the claims, the expression performing an operation “on” a signal or data (e.g., filtering, scaling, transforming, or applying gain to, the signal or data) is used in a broad sense to denote performing the operation directly on the signal or data, or on a processed version of the signal or data (e.g., on a version of the signal that has undergone preliminary filtering or pre-processing prior to performance of the operation thereon).
[0006] Throughout this disclosure including in the claims, the expression “system” is used in a broad sense to denote a device, system, or subsystem. For example, a subsystem that implements a decoder may be referred to as a decoder system, and a system including such a subsystem (e.g., a system that generates X output signals in response to multiple inputs, in which the subsystem generates M of the inputs and the other X - M inputs are received from an external source) may also be referred to as a decoder system.
[0007] Throughout this disclosure including in the claims, the term “processor” is used in a broad sense to denote a system or device programmable or otherwise configurable (e.g., with software or firmware) to perform operations on data (e.g., audio, or video or other image data). Examples of processors include a field-programmable gate array (or other configurable integrated circuit or chip set), a digital signal processor programmed and/or otherwise configured to perform pipelined processing on audio or other sound data, a programmable general purpose processor or computer, and a programmable microprocessor chip or chip set.
SUMMARY
[0008] At least some aspects of the present disclosure may be implemented via methods. Some methods may involve obtaining, by a control system a real acoustic impulse response (AIR). Some method may involve identifying, by the control system, a first portion of the real AIR that corresponds to early reflections of a direct sound and a second portion of the real AIR that corresponds to late reflections of the direct sound. Some methods may involve generating, by the control system, one or more synthesized AIRs by modifying the first portion of the real AIR and/or the second portion of the real AIR. Some methods may involve using, by the control system, the real AIR and the one or more synthesized AIRs to generate a plurality of training samples, each training sample comprising an input audio signal and a reverberated audio signal, wherein the reverberated audio signal is generated based at least in part on the input audio signal and one of the real AIR or one of the one or more synthesized AIRs, wherein the plurality of training samples are used to train a machine learning model that takes, as an input, a test audio signal with reverberation and generates, as an output, a dereverberated audio signal.
[0009] In some examples, identifying the first portion of the real AIR that corresponds to early reflections and the second portion of the real AIR that corresponds to late reflections comprises selecting a random time value within a predetermined range, wherein the first portion comprises a portion of the real AIR prior to the random time value, and wherein the second portion comprises a portion of the real AIR after the random time value. In some examples, the predetermined range is from about 20 milliseconds to about 80 milliseconds.
[0010] In some examples, modifying the second portion of the real AIR comprises truncating the second portion of the real AIR after a duration of time randomly selected from a predetermined range of late reflection durations.
[0011] In some examples, modifying the second portion of the real AIR comprises modifying amplitudes of one or more responses included in the second portion of the real AIR. In some examples, modifying the amplitudes of the one or more responses included in the second portion of the real AIR comprises: determining a target attenuation function associated with the second portion of the real AIR; and modifying the amplitudes of the one or more responses included in the second portion of the real AIR in accordance with the target attenuation function.
[0012] In some examples, the reverberated audio signal is generated by convolving the input audio signal with the one of the real AIR or the one of the one or more synthesized AIRs.
[0013] In some examples, methods may further involve adding noise to a convolution of the input audio signal with the one of the real AIR or the one of the one or more synthesized AIRs to generate the reverberated audio signal.
[0014] In some examples, methods may further involve generating additional synthesized AIRs by: identifying an updated first portion of the real AIR and an updated second portion of the real AIR; and modifying the updated first portion of the real AIR and/or the updated second portion of the real AIR.
[0015] In some examples, methods may further involve providing the plurality of training samples to the machine learning model to generate a trained machine learning model that takes, as the input, the test audio signal with reverberation and generates, as the output, the dereverberated audio signal. In some examples, the test audio signal is a live-captured audio signal.
[0016] In some examples, the real AIR is a measured AIR measured in a physical room.
[0017] In some examples, the real AIR is generated using a room acoustics model.
[0018] In some examples, the input audio signal is associated with a particular audio content type. In some examples, the particular audio content type comprises far-field noise. In some examples, the particular audio content type comprises audio content captured in an indoor environment. In some examples, methods may further involve obtaining a training set of a plurality of input audio signals each associated with the particular audio content type prior to generating the plurality of training samples.
[0019] Some or all of the operations, functions and/or methods described herein may be performed by one or more devices according to instructions (e.g., software) stored on one or more non-transitory media. Such non-transitory media may include memory devices such as those described herein, including but not limited to random access memory (RAM) devices, read-only memory (ROM) devices, etc. Accordingly, some innovative aspects of the subject matter described in this disclosure can be implemented via one or more non-transitory media having software stored thereon.
[0020] At least some aspects of the present disclosure may be implemented via an apparatus. For example, one or more devices may be capable of performing, at least in part, the methods disclosed herein. In some implementations, an apparatus is, or includes, an audio processing system having an interface system and a control system. The control system may include one or more general purpose single- or multi-chip processors, digital signal processors (DSPs), application specific integrated circuits (ASICs), field programmable gate arrays (FPGAs) or other programmable logic devices, discrete gates or transistor logic, discrete hardware components, or combinations thereof.
[0021] Details of one or more implementations of the subject matter described in this specification are set forth in the accompanying drawings and the description below. Other features, aspects, and advantages will become apparent from the description, the drawings, and the claims. Note that the relative dimensions of the following figures may not be drawn to scale. BRIEF DESCRIPTION OF THE DRAWINGS
[0022] Figure 1 shows an example of an audio signal in the time domain and in the frequency domain in accordance with some implementations.
[0023] Figure 2 shows a block diagram of an example system for performing dereverberation of audio signals in accordance with some implementations.
[0024] Figure 3 shows an example of a process for performing dereverberation of audio signals in accordance with some implementations.
[0025] Figures 4A and 4B show examples of acoustic impulse responses (AIRs).
[0026] Figure 5A shows an example of a process for generating synthesized AIRs in accordance with some implementations.
[0027] Figure 5B shows an example of a process for generating a training set using synthesized AIRs in accordance with some implementations.
[0028] Figure 6 shows an example architecture of a machine learning model for dereverberating audio signals in accordance with some implementations.
[0029] Figure 7 shows an example process for training a machine learning model for dereverberating audio signals in accordance with some implementations.
[0030] Figure 8 shows a block diagram of an example system for performing dereverberation of audio signals in accordance with some implementations.
[0031] Figure 9 shows a block diagram that illustrates examples of components of an apparatus capable of implementing various aspects of this disclosure.
[0032] Like reference numbers and designations in the various drawings indicate like elements.
DETAILED DESCRIPTION OF EMBODIMENTS
[0033] Audio signals may include various types of distortions, such as noise and/or reverberation. For example, reverberation occurs when an audio signal is distorted by various reflections off of various surfaces (e.g., walls, ceilings, floors, furniture, etc.). Reverberation may have a substantial impact on sound quality and speech intelligibility. Accordingly, dereverberation of an audio signal may be performed, for example, to improve speech intelligibility and clarity.
[0034] Sound arriving at a receiver (e.g., a human listener, a microphone, etc.) is made up of direct sound, which includes sound directly from the source without any reflections, and reverberant sound, which includes sound reflected off of various surfaces in the environment. The reverberant sound includes early reflections and late reflections. Early reflections may reach the receiver soon after or concurrently with the direct sound, and may therefore be partially integrated into the direct sound. The integration of early reflections with direct sound creates a spectral coloration effect which contributes to a perceived sound quality. The late reflections arrive at the receiver after the early reflections (e.g., more than 50-80 milliseconds after the direct sound). The late reflections may have a detrimental effect on speech intelligibility. Accordingly, dereverberation may be performed on an audio signal to reduce an effect of late reflections present in the audio signal to thereby improve speech intelligibility.
[0035] Figure 1 shows an example of a time domain input audio signal 100 and a corresponding spectrogram 102. As illustrated in spectrogram 102, early reflections may produce changes in spectrogram 104 as depicted by spectral colorations 106. Spectrogram 104 also illustrates late reflections 108, which may have a detrimental effect on speech intelligibility.
[0036] It may be difficult to perform enhancement (e.g., dereverberation and/or noise suppression) on audio signals such that speech intelligibility is improved by the enhancement, and, such that the perceptual quality of the audio signal is preserved. For example, machine learning models, such as deep neural networks, may be used to predict a dereverberation mask that, when applied to a reverberated audio signal, generates a dereverberated audio signal. However, training such machine learning models may be computationally intensive and inefficient. For example, such machine learning models may require a high degree of complexity to be able to achieve some degree of accuracy. As a more particular example, such machine learning models may include a vast number of layers, thereby requiring that a corresponding vast number of parameters be optimized. Moreover, such complex machine learning models may be prone to overfitting, due to training on limited training sets and a large number of parameters that are to be optimized. In such cases, such machine learning models may both be computationally intensive to train, and, may ultimately achieve lower performance. [0037] Disclosed herein are methods, systems, media, and techniques for enhancing audio signals using low-complexity machine learning models and/or using augmented training sets. As described herein (e.g., in connection with Figures 4A, 4B, 5A, and 5B), augmented training sets may be generated by generating synthesized acoustic impulse responses (AIRs). Augmented training sets may be able to better span potential combinations of room environments, noise, speaker types, etc., that may allow a machine learning model to be trained using a larger and more representative training set, thereby alleviating the problem of model overfitting. Additionally, as described herein, a low-complexity machine learning model may be used that utilizes a convolutional neural network (CNN) with a relatively small number of layers (and therefore, a relatively small number of parameters to be optimized) in combination with a recurrent element. By combining a CNN with a recurrent element in parallel (e.g., as shown in and described below in connection with Figure 6), a low-complexity machine learning model may be trained that generates smooth enhancement masks in a computationally-efficient manner. In particular, the recurrent element may inform the CNN portions of audio signals that are to be used in subsequent iterations of training, thereby leading to smoother predicted enhancement masks. Examples of recurrent elements that may be used include a gated recurrent unit (GRU), a long short-term memory (LSTM) network, an Elman recurrent neural network (RNN), and/or any other suitable recurrent element. Moreover, a loss function is described herein that allows a machine learning model to both generate a predicted enhanced audio signal that is accurate with respect to the signal of interest in the input distorted audio signal as well as to optimize for minimizing a degree of reverberation in the predicted clean audio signal. In particular, such a loss function, as described in more detail in connection with Figure 7, may incorporate a parameter that approximates a degree of reverberation in a predicted clean audio signal, thereby allowing the machine learning model to be trained based on the ultimate parameter of interest - that is, whether an output signal is substantially dereverberated in comparison to an input signal.
[0038] In some implementations, an input audio signal can be enhanced using a trained machine learning model. In some implementations, the input audio signal can be transformed to a frequency domain by extracting frequency domain features. In some implementations, a perceptual transformation based on processing by the human cochlea can be applied to the frequency-domain representation to obtain banded features. Examples of a perceptual transformation that may be applied to the frequency -domain representation include a Gammatone filter, an equivalent rectangular bandwidth filter, a transformation based on the Mel scale, or the like. In some implementations, the frequency-domain representation may be provided as an input to a trained machine learning model that generates, as an output, a predicted enhancement mask. The predicted enhancement mask may be a frequency -domain representation of a mask that, when applied to the frequency-domain representation of the input audio signal, generates an enhanced audio signal. In some implementations, an inverse of the perceptual transformation may be applied to the predicted enhancement mask to generate a modified predicted enhancement mask. A frequency-domain representation of the enhanced audio signal may then be generated by multiplying the frequency- domain representation of the input audio signal by the modified predicted enhancement mask. An enhanced audio signal may then be generated by transforming the frequency-domain representation of the enhanced audio signal to the time-domain.
[0039] In other words, a trained machine learning model for enhancing audio signals may be trained to generate, for a given frequency-domain input audio signal, a predicted enhancement mask that, when applied to the frequency -domain input audio signal, generates a frequency-domain representation of a corresponding enhanced audio signal. In some implementations, a predicted enhancement mask may be applied to a frequency -domain representation of the input audio signal by multiplying the frequency-domain representation of the input audio signal and the predicted enhancement mask. Alternatively, in some implementations, the logarithm of the frequency- domain representation of the input audio signal may be taken. In such implementations, a frequency domain representation of the enhanced audio signal may be obtained by subtracting the logarithm of the predicted enhancement mask from the logarithm of the frequency-domain representation of the enhanced audio signal.
[0040] It should be noted that, in some implementations, training a machine learning model may include determining weights associated with one or more nodes and/or connections between nodes of the machine learning model. In some implementations, a machine learning model may be trained on a first device (e.g., a server, a desktop computer, a laptop computer, or the like). Once trained, the weights associated with the trained machine learning model may then be provided (e.g., transmitted to) a second device (e.g., a server, a desktop computer, a laptop computer, a media device, a smart television, a mobile device, a wearable computer, or the like) for use by the second device in dereverberating audio signals.
[0041] Figures 2 and 3 show examples of systems and techniques for dereverberating audio signals. It should be noted that although Figures 2 and 3 describe dereverberating audio signals, the systems and techniques described in connection with Figures 2 and 3 may be applied to other types of enhancement, such as noise suppression, a combination of noise suppression and dereverberation, or the like. In other words, rather than generating a predicted dereverberation mask and a predicted dereverberated audio signal, in some implementations, a predicted enhancement mask may be generated, and the predicted enhancement mask may be used to generate a predicted enhanced audio signals, where the predicted enhanced audio signal is a denoised and/or dereverberated version of a distorted input audio signal.
[0042] Figure 2 shows an example of a system 200 for dereverberating audio signals in accordance with some implementations. As illustrated, a dereverberation audio component 206 takes, as an input, an input audio signal 202, and generates, as an output, a dereverberated audio signal 204. In some implementations, dereverberation audio component 206 includes a feature extractor 208. Feature extractor 208 may generate a frequency-domain representation of input audio signal 202, which may be considered the input signal spectrum. The input signal spectrum may then be provided to a trained machine learning model 210. The trained machine learning model 210 may generate, as an output, a predicted dereverberation mask. The predicted dereverberation mask may be provided to a dereverberated signal spectrum generator 212. Dereverberated signal spectrum generator 212 may apply the predicted dereverberation mask to the input signal spectrum to generate a dereverberated signal spectrum (e.g., a frequency-domain representation of the dereverberated audio signal). The dereverberated signal spectrum may then be provided to a time-domain transformation component 214. Time-domain transformation component 214 may generated dereverberated audio signal 204.
[0043] Figure 3 shows an example process 300 for dereverberating audio signals in accordance with some implementations. In some implementations, the system shown in and described above in connection with Figure 2 may implement blocks of process 300 to generate dereverberated audio signals. In some implementations, blocks of process 300 may be implemented by a user device, such as a mobile phone, a tablet computer, a laptop computer, a wearable computer (e.g., a smart watch, etc.), a desktop computer, a gaming console, a smart television, or the like. In some implementations, blocks of process 300 may be performed in an order not shown in Figure 3. In some implementations, one or more blocks of process 300 may be omitted. In some implementations, two or more blocks of process 300 may be performed substantially in parallel.
[0044] Process 300 can begin at 302 by receiving an input audio signal that includes reverberation. The input audio signal may be a bve-captured audio signal, such as live-streamed content, an audio signal corresponding to an in-progress video conference or audio conference, or the like. In some implementations, the input audio signal may be a pre-recorded audio signal, such as an audio signal associated with pre-recorded audio content (e.g., television content, a video, a movie, a podcast, or the like). In some implementations, the input audio signal may be received by a microphone of the user device. In some implementations, the input audio signal may be transmitted to the user device, such as from a server device, another user device, or the like.
[0045] At 304, process 300 can extract features of the input audio signal by generating a frequency-domain representation of the input audio signal. For example, process 300 can generate a frequency-domain representation of the input audio signal using a transform, such as a short-time Fourier transform (STFT), a modified discrete cosine transform (MDCT), or the like. In some implementations, the frequency-domain representation of the input audio signal is referred to herein as “binned features” of the input audio signal. In some implementations, the frequency- domain representation of the input audio signal may be modified by applying a perceptually-based transformation that mimics filtering of the human cochlea. Examples of perceptually-based transformations include a Gammatone filter, an equivalent rectangular bandwidth filter, a Mel- scale filter, or the like. The modified frequency -domain transformation is sometimes referred to herein as “banded features” of the input audio signal.
[0046] At 306, process 300 can provide the extracted features (e.g., the frequency -domain representation of the input audio signal or the modified frequency -domain representation of the input audio signal) to a trained machine learning model. The machine learning model may have been trained to generate a dereverberation mask that, when applied to the frequency-domain representation of the input audio signal, generates a frequency -domain representation of a dereverberated audio signal. In some implementations, the logarithm of the extracted features may be provided to the trained machine learning model.
[0047] The machine learning model may have any suitable architecture or topology. For example, in some implementations, the machine learning model may be or may include a deep neural network, a convolutional neural network (CNN), a long short-term memory (LSTM) network, a recurrent neural network (RNN), or the like. In some implementations, the machine learning model may combine two or more types of networks. For example, in some implementations, the machine learning model may combine a CNN with a recurrent element. Examples of recurrent elements that may be used include a GRU, an LSTM network, an Elman RNN, or the like. An example of a machine learning model architecture that combines a CNN with a GRU is shown in and described below in connection with Figure 6. Note that techniques for training a machine learning model are shown in and described below in connection with Figure 7.
[0048] At 308, process 300 can obtain, from an output of the trained machine learning model, a predicted dereverberation mask that, when applied to the frequency-domain representation of the input audio signal, generates a frequency -domain representation of the dereverberated audio signal. In some implementations, process 300 can modify the predicted dereverberation mask by applying an inverse perceptually-based transformation, such as an inverse Gammatone filter, an inverse equivalent rectangular bandwidth filter, or the like.
[0049] At 310, process 300 can generate a frequency-domain representation of the dereverberated audio signal based on the predicted dereverberation mask generated by the trained machine learning model and the frequency-domain representation of the input audio signal. For example, in some implementations, process 300 can multiply the predicted dereverberation mask by the frequency-domain representation of the input audio signal. In instances in which the logarithm of the frequency-domain representation of the input audio signal was provided to the trained machine learning model, process 300 can generate the frequency-domain representation of the dereverberated audio signal by subtracting the logarithm of the predicted reverberation mask from the logarithm of the frequency -domain representation of the input audio signal. Continuing with this example, process 300 can then exponentiate the difference of the logarithm of the predicted reverberation mask and the logarithm of the frequency-domain representation of the input audio signal to obtain the frequency-domain representation of the dereverberated audio signal.
[0050] At 312, process 300 can generate a time-domain representation of the dereverberated audio signal. For example, in some implementations, process 300 can generate the time-domain representation of the dereverberated audio signal by applying an inverse transform (e.g., an inverse STFT, an inverse MDCT, or the like) to the frequency-domain representation of the dereverberated audio signal.
[0051] Process 300 can end at 314.
[0052] In some implementations, after generating the time-domain representation of the dereverberated audio signal, the dereverberated audio signal may be played or presented (e.g., by one or more speaker devices of a user device). In some implementations, the dereverberated audio signal may be stored, such as in local memory of the user device. In some implementations, the dereverberated audio signal may be transmitted, such as to another user device for presentation by the other user device, to a server for storage, or the like.
[0053] In some implementations, a machine learning model for dereverberating audio signals may be trained using a training set. The training set may include any suitable number of training samples (e.g., 100 training samples, 1000 training samples, 10,000 training samples, or the like), where each training sample includes a clean audio signal (e.g., with no reverberation), and a corresponding reverberated audio signal. As described above in connection with Figures 2 and 3, the machine learning model may be trained, using the training set, to generate a predicted dereverberation mask that, when applied to a particular reverberated audio signal, generates a predicted dereverberated audio signal.
[0054] Training a machine learning model that can robustly generate predicted dereverberation masks for different reverberated audio signals may depend on the quality of the training set. For example, for a machine learning model to be robust, the training set may need to capture reverberation from a vast number of different room types (e.g., rooms having different sizes, layouts, furniture, etc.), a vast number of different speakers, etc. Acquiring such a training set is difficult. For example, a training set may be generated by applying various AIRs that each characterize a room reverberation to a clean audio signal, thereby generating pairs of a clean audio signal and a corresponding reverberated audio signal generated by convolving an AIR with the clean audio signal. However, there may be a limited number of real AIRs available, and the real AIRs that are available may not fully characterize potential reverberation effects (e.g., by not adequately capturing rooms of different dimensions, layouts, etc.).
[0055] Disclosed herein are techniques for generating an augmented training set that may be used to train a robust machine learning model for dereverberating audio signals. In some implementations, real AIRs are used to generate a set of synthesized AIRs. The synthesized AIRs may be generated by altering and/or modifying various characteristics of early reflections and/or late reflections of a measured AIR, as shown in and described below in connection with Figures 4A, 4B, and 5A. In some implementations, a real AIR may be a measured AIR that is measured in a room environment (e.g., using one or more microphones positioned in the room). Alternatively, in some implementations, a real AIR may be a modeled AIR, generated, for example, using a room acoustics model that incorporates room shape, materials in the room, a layout of the room, objects (e.g., furniture) within the room, and/or any combination thereof. By contrast, a synthesized AIR may be an AIR that is generated based on a real AIR (e.g., by modifying components and/or characteristics of the real AIR), regardless of whether the real AIR is measured or generated using a room acoustics model. In other words, a real AIR may be considered a starting point for generating one or more synthesized AIRs. Techniques for generating synthesized AIRs are shown in and described below in connection with Figure 5A. The real and/or synthesized AIRs may then be used to generate a training set that includes training samples generated based on the real and synthesized AIRs, as shown in and described below in connection with Figure 5B. For example, a training sample may include a clean audio signal and a corresponding reverberated audio signal that has been generated by convolving a synthesized AIR with the clean audio signal. Because many synthesized AIRs may be generated from a single real AIR, and because multiple reverberated audio signals may be generated from a single clean audio signal and a single AIR (whether measured or synthesized), the augmented training set may include a larger number of training samples that better capture the extend of potential reverberation effects, thereby leading to a more robust machine learning model when trained with the augmented training set.
[0056] Figure 4A shows an example of a measured AIR in a reverberant environment. As illustrated, early reflections 402 may arrive at a receiver concurrently or shortly after a direct sound 406. By contrast, late reflections 404 may arrive at the receiver after early reflections 402. Late reflections 404 are associated with a duration 408, which may be on the order of 100 milliseconds, 0.5 seconds, 1 second, 1.5 seconds, or the like. Late reflections 404 are also associated with a decay 410 that characterizes how an amplitude of late reflections 404 attenuates or decreases over time. In some instances, decay 410 may be characterized as an exponential decay, a linear function, a portion of a polynomial function, or the like. The boundary between early reflections and late reflections may be within a range of about 50 milliseconds and 80 milliseconds.
[0057] Figure 4B shows a schematic representation of how the AIR depicted in Figure 4A may be modified to generate a synthesized AIR. In some implementations, a time of a component of early reflections 402 may be modified. For example, as illustrated in Figure 4B, a time of early reflection component 456 may be modified in the synthesized AIR, for example, to be earlier or later than a time of the early reflection component in the measured AIR. In some implementations, the duration of the late reflections may be modified. For example, referring to the synthesized AIR depicted in Figure 4B, duration 458 is truncated relative to duration 408 of the corresponding measured AIR. In some implementations, a shape of a decay of the late reflections may be modified in the synthesized AIR. For example, referring to the synthesized AIR depicted in Figure 4B, decay 458 is steeper than corresponding decay 408 of the measured AIR, causing late reflection components of the synthesized AIR to be more attenuated relative to the measured AIR.
[0058] Figure 5A shows an example of a process 500 for generating one or more synthesized AIRs from a single real AIR. In some implementations, blocks of process 500 may be implemented by a device that generates an augmented training set for training of a machine learning model for dereverberating audio signals, such as a server, a desktop computer, a laptop computer, or the like. In some implementations, two or more blocks of process 500 may be performed substantially in parallel. In some implementations, blocks of process 500 may be performed in an order not shown in Figure 5A. In some implementations, one or more blocks of process 500 may be omitted.
[0059] Process 500 can begin at 502 by obtaining an AIR. The AIR may be a real AIR. For example, the AIR may be measured using a set of microphones within a reverberant room environment. As another example, the AIR may be an AIR generated using a room acoustics model. The AIR may be obtained from any suitable source, such as a database that stores measured AIRs, or the like.
[0060] At 504, process 500 can identify a first portion of the AIR that corresponds to early reflections of a direct sound and a second portion of the AIR that corresponds to late reflections of the direct sound. In some implementations, process 500 can identify the first portion and the second portion by identifying a separation boundary between early reflections and late reflections in the AIR. The separation boundary may correspond to a time point in the AIR that divides the AIR into early reflections and late reflections. In some implementations, the separation boundary may be identified by selecting a random value from within a predetermined range. Examples of the predetermined range include 15 milliseconds - 85 milliseconds, 20 milliseconds - 80 milliseconds, 30 milliseconds - 70 milliseconds, or the like. In some implementations, the separation boundary may be a random value selected from any suitable distribution corresponding to the predetermined range (e.g., a uniform distribution, a normal distribution, or the like).
[0061] At 506, process 500 can generate one or more synthesized AIRs by modifying portions of the early reflections and/or the late reflections of the AIR. In some implementations, the early reflections and the late reflections may be identified within the AIR based on the separation boundary identified at block 504. In some implementations, process 500 may generate a synthesized AIR by modifying portions of the early reflections of the AIR. For example, as shown in and described above in connection with Figure 4B, process 500 may modify time points of one or more components of the early reflection. In some implementations, process 500 may modify an order of one or more components of the early reflection. For example, in some implementations, process 500 may modify the order of the one or more components of the early reflection such that the one or more components of the early reflection have different time points within the early reflection part of the AIR. In some implementations, components of the early reflection portion of the AIR may be randomized.
[0062] In some implementations, process 500 may generate a synthesized AIR by modifying portions of the late reflections of the AIR. For example, as shown in and described above in connection with Figure 4B, process 500 may modify a duration of the late reflections in the synthesized AIR by randomly selecting a time duration after which to truncate the late reflections from a predetermined range. In some implementations, the predetermined range may be determined based on a time point that separates the first portion of the AIR and the second portion of the AIR (e.g., the separation boundary) identified at block 502. For example, in some implementations, the late reflections may be truncated at a randomly selected time duration selected from the range of from the separation boundary to 1 second, from the separation boundary to 1.5 seconds, or the like.
[0063] As another example, in some implementations, process 500 may generate a synthesized AIR by modifying a decay associated with the late reflections. As a more particular example, in some implementations, process 500 may generate a decay function (e.g., an exponential decay function, a linear decay, etc.). Continuing with this more particular example, process 500 may then modify amplitudes of components of the late reflections subject to the generated decay function. In some implementations, this may cause the synthesized AIR to have late reflection components that are attenuated relative to the corresponding late reflection components of the measured AIR. Conversely, in some implementations, this may cause the synthesized AIR to have late reflection components that are amplified or boosted relative to the corresponding late reflection components of the measured AIR. Modification of the decay associated with the late reflections may change a reverberation time (RT), such as the time for reverberation to decrease by 60 dB (e.g., the RT60). [0064] It should be noted that, in some implementations, a synthesized AIR may include modifications to both the early reflection components and the late reflection components. Moreover, in some implementations, early reflection components and/or late reflection components may be modified in multiple ways in a synthesized AIR relative to the real AIR. For example, in some implementations, a synthesized AIR may include late reflections that have both been truncated and late reflection components that have been modified in amplitude based at least in part on a modified decay applied to the late reflections of the synthesized AIR.
[0065] Additionally, in some implementations, the synthesized AIR may be further modified, e.g., in post-processing. For example, in some implementations, a direct-to-reverberant ratio (DRR) associated with the synthesized AIR may be modified. As a more particular example, in some implementations, the DRR associated with the synthesized AIR may be modified by applying a gain to a portion (e.g., an early reflection portion of the synthesized AIR) to increase or decrease the DRR. In some implementations, multiple modified synthesized AIRs may be generated from a single synthesized AIR. For example, in some implementations, multiple modified synthesized AIRs may be generated by applying different gains, each corresponding to a different modified synthesized AIR, to the single synthesized AIR.
[0066] At 508, process 500 can determine whether additional synthesized AIRs are to be generated based on the AIR obtained at block 502. In some implementations, process 500 can determine whether additional synthesized AIRs are to be generated based on whether a target or threshold number of synthesized AIRs that are to be generated from the AIR have been generated. For example, in an instance in which N synthesized AIRs are to be generated from a particular AIR, process 500 can determined whether N synthesized AIRs have been generated from the AIR obtained at block 502. It should be noted that N may be any suitable value, such as 1, 5, 10, 20, 50, 100, 500, 1000, 2000, etc.
[0067] If, at 508, process 500 determines that additional synthesized AIRs are not to be generated (“no” at block 508), process 500 can end at 510. Conversely, if, at block 508, process 500 determines that additional synthesized AIRs are to be generated (“yes” at block 508), process 500 can loop back to block 504 and can identify a different first portion of the AIR and second portion of the AIR obtained at block 502. By looping through blocks 504-508, process 500 may generate multiple synthesized AIRs from a single measured AIR. [0068] Figure 5B shows an example of a process 550 for generating an augmented training set using real and/or synthesized AIRs. The augmented training set may be used for training a machine learning model for dereverberating audio signals. In some implementations, blocks of process 550 may be implemented by a device suitable for generating an augmented training set, such as a server, a desktop computer, a laptop computer, or the like. In some implementations, the device may be the same as the device that implemented blocks of process 500, as shown in and described above in connection with Figure 5A. In some implementations, two or more blocks of process 550 may be performed substantially in parallel. In some implementations, blocks of process 550 may be performed in an order other than what is shown in Figure 5B. In some implementations, one or more blocks of process 550 may be omitted.
[0069] Process 550 can begin at 552 by obtaining a set of clean input audio signals (e.g., input audio signals without any reverberation and/or noise). The clean input audio signals in the set of clean input audio signals may have been recorded by any suitable number of devices (or microphones associated with any suitable number of devices). For example, in some implementations, two or more of the clean input audio signals may have been recorded by the same device. As another example, in some implementations, each of the clean input audio signals may have been recorded by a different device. In some implementations, two or more of the clean input audio signals may have been recorded in the same room environment. In some implementations, each of the clean input audio signals may have been recorded in a different room environment. In some implementations, a clean input audio signal in the set of clean input audio signals may include any combination of types of audible sounds, such as speech, music, sound effects, or the like. However, each clean input audio signal may be devoid of reverberation, echo, and/or noise.
[0070] At block 554, process 550 can obtain a set of AIRs that include real AIRs and/or synthesized AIRs. The set of AIRs may include any suitable number of AIRs (e.g., 100 AIRs, 200 AIRs, 500 AIRs, or the like). The set of AIRs may include any suitable ratio of real AIRs to synthesized AIRs, such as 90% synthesized AIRs and 10% real AIRs, 80% synthesized AIRs and 20% real AIRs, or the like. More detailed techniques for generating synthesized AIRs are shown in and described above in connection with Figure 5A.
[0071] At block 556, process 550 can, for each pairwise combination of clean input audio signal in the set of clean input audio signals and AIR in the set of AIRs, generate a reverberated audio signal based on the clean input audio signal and the AIR. For example, in some implementations, process 550 can convolve the AIR with the clean input audio signal to generate the reverberated audio signal. In some implementations, given N clean input audio signals and M AIRs, process 550 can generate up to N x M reverberated audio signals.
[0072] In some implementations, at block 558, process 550 can, for one or more of the reverberated audio signals generated at block 556, add noise to generate a noisy reverberated audio signal. Examples of noise that may be added include white noise, pink noise, brown noise, multi talker speech babble, or the like. Process 550 may add different types of noise to different reverberated audio signals. For example, in some implementations, process 550 may add white noise to a first reverberated audio signal to generate a first noisy reverberated audio signal. Continuing with this example, in some implementations, process 550 may add multi-talker speech babble type noise to the first reverberated audio signal to generate a second noisy reverberated audio signal. Continuing still further with this example, in some implementations, process 550 may add brown noise to a second reverberated audio signal to generate a third noisy reverberated audio signal. In other words, in some implementations, different versions of a noisy reverberated audio signal may generated by adding different types of noise to a reverberated audio signal. It should be noted that, in some implementations, block 558 may be omitted, and the training set may be generated without adding noise to any reverberated audio signals.
[0073] At the end of block 558, process 550 has generated a training set comprising multiple training samples. Each training sample may include a clean audio signal and a corresponding reverberated audio signal. The reverberated audio signal may or may not include added noise. It should be noted that, in some implementations, a single clean audio signal may be associated with multiple training samples. For example, a clean audio signal may be used to generate multiple reverberated audio signals by convolving the clean audio signal with multiple different AIRs. As another example, a single reverberated audio signal (e.g., generated by convolving a single clean audio signal with a single AIR) may be used to generated multiple noisy reverberated audio signals, each corresponding to a different type of noise added to the single reverberated audio signal. Accordingly, a single clean audio signal may be associated with 10, 20, 30, 100, or the like training samples, each comprising a different corresponding reverberated audio signal (or noisy reverberated audio signal).
[0074] In some implementations, an augmented training set may be generated for a particular type of audio content. For example, the particular type of audio content may correspond to a type of audio content for which dereverberation may be particularly difficult. By way of example, it may be difficult to perform dereverberation on audio signals that include far-field noise, such as the noise of a dog barking or a baby crying in the background of an audio signal that includes near- field speech (e.g., from a video conference, from an audio call, or the like). Difficulty in performing dereverberation on far-field noise may lead to poor noise management (e.g., denoising of the audio signal). Because dereverberation of far-field noise may be dependent on both room characteristics/acoustics and/or the particular noise, it may be difficult to train a model to perform dereverberation on such far-field noise. For example, a training dataset used to train such a model may not have enough training samples of the particular type of far-field noise present in an expansive set of room acoustics, thereby making the model trained with such a limited training set less robust. Accordingly, generating an augmented training set for a particular type of audio content may allow for a more robust model to be trained. In some implementations, the particular type of audio content may include particular types of sounds or events (e.g., a dog barking, a baby crying, an emergency siren passing by, or the like) and/or particular audio environments (e.g., an indoor environment, an outdoor environment, an indoor shared workspace, or the like). In some implementations, the augmented training set may be generated by first identifying a training set of audio signals that include the particular type of audio content. For example, a training set that includes dogs barking in the background of near-field speech may be obtained. As another example, a training set that includes a far-field siren passing by in the background of near-field speech may be obtained. In some implementations, because reverberation is generally present in indoor environments, a training set that includes audio content captured in indoor environments (and that does not include audio content generated in outdoor environments) may be obtained. Note that, in some implementations, the training set may be obtained by applying audio signals from a corpus of audio signals that classifies each audio signals as associated with the particular type of audio content. In some implementations, the augmented training set may be generated by applying synthesized AIRs and/or noise of a particular type (e.g., speech noise, indoor room noise, etc.) to the identified training set to generate the augmented training set.
[0075] It should be noted that, in some implementations, an augmented training set may be used for training speech enhancement models other than dereverberation models. For example, in some implementations, such an augmented training set may be used to train machine learning models for noise management (e.g., denoising), machine learning models that perform a combination of noise management and dereverberation, or the like. [0076] A machine learning model for dereverberating audio signals may have various types of architectures. The machine learning model may take, as an input, a frequency-domain representation of a reverberated audio signal and produce, as an output, a predicted dereverberation mask that, when applied to the frequency-domain representation of the reverberated audio signal, generates a frequency -domain representation of a dereverberated (e.g., clean) audio signal. Example architecture types include a CNN, an LSTM, an RNN, a deep neural network, or the like. In some implementations, a machine learning model may combine two or more architecture types, such as a CNN and a recurrent element. In some such implementations, a CNN may be used to extract features of an input reverberated audio signal at different resolutions. In some implementations, a recurrent element may serve as a memory gate that controls an amount of previously provided input data that is used by the CNN. Use of a recurrent element in combination with a CNN may allow the machine learning model to produce smoother outputs. Additionally, use of a recurrent element in combination with a CNN may allow the machine learning model to achieve a higher accuracy and with a decreased training time. Accordingly, use of a recurrent element in combination with a CNN may improve computational efficiency by decreasing time and/or computational resources used to train a robust, accurate machine learning model for dereverberating audio signals. Examples of types of recurrent elements that may be used include a GRU, an LSTM network, an Elman RNN, and/or any other suitable type of recurrent element or architecture.
[0077] In some implementations, a recurrent element may be combined with a CNN such that the recurrent element and the CNN are in parallel. For example, outputs of the recurrent element may be provided to one or more layers of the CNN such that the CNN generates an output based on outputs of layers of the CNN and based on an output of the recurrent element.
[0078] In some implementations, a CNN utilized in a machine learning model may include multiple layers. Each layer may extract features of an input reverberated audio signal spectrum (e.g., a frequency-domain representation of the reverberated audio signal) at different resolutions. In some implementations, layers of the CNN may have different dilation factors. Use of dilation factors greater than 1 may effectively increase the receptive field of a convolution filter used for a particular layer having a dilation factor greater than 1 but without increasing the number of parameters. Use of dilation factors greater than 1 may therefore allow a machine learning model to be more robustly trained (by increasing receptive field size) while not increasing in complexity (e.g., by maintaining a number of parameters to be learned or optimized). In one example, a CNN may have a first group of layers, each having an increasing dilation rate, and a second group of layers, each having a decreasing dilation rate. In one specific example, the first group of layers may include 6 layers, having dilation factors of 1, 2, 4, 8, 12, and 20, respectively. Continuing with this example, the second group of layers may include 5 layers decreasing in dilation factor (e.g., 5 layers having dilation factors of 12, 8, 4, 2, and 1, respectively). The size of the receptive field considered by the CNN is related to the dilation factors, the convolution filter size, a stride size, and/or a pad size (e.g., whether or not the model is causal). By way of example, given 6 CNN layers with increasing dilation factors of 1, 2, 4, 8, 12, and 20, a convolution filter size of 3x3, a stride of 0, and a causal model, the CNN may have a total receptive field of (2x(l+2+4+8+12+20))+l frames, or 95 frames. As another example, the same network with 0 dilation would have a receptive field size of (2*(1+1+1+1+1+1))+1=13. In some implementations, the total receptive field may correspond to a delay line duration that indicates a duration of the spectrum that is considered by the machine learning model. It should be noted that the dilation factors described above are merely exemplary. In some implementations, smaller dilation factors may be used to, for example, decrease a delay duration for real-time audio signal duration.
[0079] In some implementations, the machine learning model may be zero latency. In other words, the machine learning model may not use look ahead, or future data points. This is sometimes referred to as the machine learning model being causal. Conversely, in some implementations, the machine learning model may implement layers that utilize look ahead blocks.
[0080] Figure 6 shows an example of a machine learning model 600 that combines a CNN 606 and a GRU 608 in parallel. As illustrated, machine learning model 600 takes, as an input 602, a reverberated audio signal spectrum (e.g., a frequency -domain representation of the reverberated audio signal) and generates an output 604 corresponding to a predicted dereverberation mask.
[0081] As illustrated, CNN 606 includes a first set of layers 610 that have increasing dilation factors. In particular, first set of layer 610 includes 6 layers with dilation factors of 1, 2, 4, 8, 12, and 20, respectively. First set of layers 610 is followed by a second set of layers 612 that have decreasing dilation factors. In particular, second set of layers 612 includes 5 layers with dilation factors of 12, 8, 4, 2, and 1. Second set of layers 612 is followed by a third set of layers 614, which each have a dilation factor of 1. In some implementations, first set of layers 610, second set of layers 612, and third set of layers 614 may each include convolutional blocks. Each convolutional block may utilize a convolutional filter. Although CNN 606 utilizes convolutional filters of a 3x3 size, this is merely exemplary, and, in some implementations, other filter sizes (e.g., 4x4, 5x5, or the like) may be used. As illustrated in Figure 6, each layer of CNN 606 may feed forward to a next, or subsequent layer of CNN 606. Additionally, in some implementations, an output of a layer with a particular dilation factor may be provided as an input to a second layer having the same dilation factor. For example, a layer of first set of layers 610 having a dilation factor of 2 may be provided via a connection 614 to a layer of second set of layers 612 having a dilation factor of 2. Connections 616, 618, and 620 similarly provide connections between layers having the same dilation factors.
[0082] As illustrated in Figure 6, an output of GRU 608 may be provided to various layers of CNN 606 such that CNN 606 generates output 604 based on the layers of CNN 606 as well as the output of GRU 608. For example, as illustrated in Figure 6, GRU 608 may provide an output to layers having decreasing dilation factors (e.g., to layers included in second set of layers 612) via connections 622, 624, 626, 628, 630, and 632. GRU 608 may have any suitable number of nodes (e.g., 48, 56, 64, or the like) and/or any suitable number of layers (e.g., 1, 2, 3, 4, 8, or the like). In some implementations, GRU 608 may be preceded by a first reshape block 634 which reshapes dimensions of input 602 to dimensions suitable for and/or required by GRU 608. A second reshape block 636 may follow GRU 608. Second reshape block 636 may reshape dimensions of an output generated by GRU 608 to dimensions suitable for provision to each layer of CNN 606 that receives the output of GRU 608.
[0083] In some implementations, a machine learning model may be trained using a loss function that indicates a degree of reverberation associated with a predicted dereverberated audio signal generated using a predicted dereverberation mask generated by the machine learning model. By training the machine learning model to minimize a loss function that includes an indication of a degree of reverberation, the machine learning model may not only generate dereverberated audio signals similar in content to the corresponding reverberated audio signals (e.g., including similar direct sound content as in the reverberated audio signal), but additionally, generate dereverberated audio signals with less reverberation. In some implementations, a loss term, for a particular training sample, may be a combination of a difference between a predicted dereverberated audio signal and a ground-truth clean audio signal and a degree of reverberation associated with the predicted dereverberated audio signal. [0084] In some implementations, a degree of reverberation included in a loss function may be a speech-to-reverberation modulation energy. In some implementations, the speech-to- reverberation modulation energy may be a ratio of modulation energy at relatively high modulation frequencies relative to modulation energy over all modulation frequencies. In some implementations, the speech-to-reverberation modulation energy may be a ratio of modulation energy at relatively high modulation frequencies relative to modulation energy over relatively low modulation frequencies. In some implementations, relatively high modulation frequencies and relatively low modulation frequencies may be identified based on modulation filters. For example, in an instance in which modulation energy is determined at M modulation frequency bands, the highest N of the M (e.g., 3, 4, 5, etc.) modulation frequency bands may be considered as corresponding to “high modulation frequencies,” and the remaining bands (e.g., M-N) may be considered as corresponding to “low modulation frequencies.”
[0085] Figure 7 shows an example of a process 700 for training a machine learning model using a loss function that incorporates a degree of reverberation of a predicted dereverberated audio signal in accordance with some implementations. In some implementations, blocks of process 700 may be implemented by a device, such as a server, a desktop computer, a laptop computer, or the like. In instances in which an augmented training set is constructed to train the machine learning model, a device that implements blocks of process 700 may be the same device or a different device as that used to construct the augmented training set. In some implementations, two or more blocks of process 700 may be executed substantially in parallel. In some implementations, blocks of process 700 may be performed in an order other than what is shown in Figure 7. In some implementations, one or more blocks of process 700 may be omitted.
[0086] Process 700 can begin at 702 by obtaining a training set that includes training samples that comprise pairs of reverberated audio signals and clean audio signals. In some implementations, the clean audio signals may be considered “ground-truth” signals that the machine learning model is to be trained to predict, or generate. In some implementations, the training set may be an augmented training set that has been constructed using synthesized AIRs, as described above in connection with Figures 4A, 4B, 5A, and 5B. In some implementations, process 700 may obtain the training set from a database, a remote server, or the like.
[0087] At 704, for a given training sample (e.g., for a given pair of a reverberated audio signal and a clean audio signal), process 700 can provide the reverberated audio signal to a machine learning model to obtain a predicted dereverberation mask. In some implementations, process 700 may provide the reverberated audio signal by determining a frequency-domain representation of the reverberated audio signal and providing the frequency-domain representation of the reverberated audio signal. In some implementations, the frequency-domain representation of the reverberated audio signal may have been filtered or otherwise transformed using a filter that approximates filtering of the human cochlea, as shown in and described above in connection with block 304 of Figure 3.
[0088] It should be noted that the machine learning model may have any suitable architecture. For example, the machine learning model may include a deep neural network, a CNN, an LSTM, an RNN, or the like. In some implementations, the machine learning model may combine two or more architectures, such as a CNN and a recurrent element. In some implementations, a CNN may use dilation factors at different layers. A specific example of a machine learning model that may be used is shown in and described above in connection with Figure 6.
[0089] At 706, process 700 can obtain a predicted dereverberated audio signal using the predicted dereverberation mask. For example, in some implementations, process 700 can apply the predicted dereverberation mask to the frequency-domain representation of the reverberated audio signal to obtain a frequency-domain representation of the dereverberated audio signal, as shown in and described above in connection with block 310 of Figure 3. Continuing with this example, in some implementations, process 700 can then generate a time-domain representation of the dereverberated audio signal, as shown in and described above in connection with block 312 of Figure 3.
[0090] At 708, process 700 can determine a value of a reverberation metric associated with the predicted dereverberated audio signal. The reverberation metric may be a speech-to-reverberation modulation energy (generally denoted herein as fsrmAz), where z is the predicted dereverberated audio signal) of one or more frames of the predicted dereverberated audio signal. An example equation to determine the speech-to-reverberation modulation energy that considers a ratio of energy in relatively high modulation frequencies to energy in relatively low modulation frequencies is given by: [0091] In the equation given above, Zj,k represents the average modulation energy over frames of the 7th critical band grouped by the klb modulation filter, where there are 23 critical bands and 8 modulation bands. Higher values of fsrmr(z ) are indicative of a higher degree of reverberation. It should be noted that other numbers of critical bands and/or modulation bands may be used to determine the speech-to-reverberation modulation energy.
[0092] At 710, process 700 can determine a loss term based on the clean audio signal, the predicted dereverberated audio signal, and the value of the reverberation metric. In some implementations, the loss term may be a combination of a difference between the clean audio signal and the predicted dereverberated audio signal and the value of the reverberation metric. In some implementations, the combination may be a weighted sum, where the value of the reverberation metric is weighted by an importance of minimizing reverberation in outputs produced using the machine learning model. An example equation of the loss term for a particular predicted dereverberated audio signal (denoted herein as yWe) and a particular clean audio signal (denoted herein as yrej) is given by:
[0093] As illustrated in the above equation, the loss term may be increased in instances in which there is a relatively high degree of reverberation in the predicted clean audio signal and/or in which the predicted dereverberated audio signal differs substantially from the ground-truth clean audio signal.
[0094] At 712, process 700 can update weights of the machine learning model based at least in part on the loss term. For example, in some implementations, process 700 may use gradient descent and/or any other suitable technique to calculate updated weight values associated with the machine learning model. The weights may be updated based on other factors, such as a learning rate, a dropout rate, etc. The weights may be associated with various nodes, layers, etc., of the machine learning model.
[0095] At block 714, process 700 can determine whether the machine learning model is to continue being trained. Process 700 can determine whether the machine learning model is to continue being trained based on a determination of whether a stopping criteria has been reached. The stopping criteria may include a determination that an error associated with the machine learning model has decreased below a predetermined error threshold, that weights associated with the machine learning model are being changed from one iteration to a next by less than a predetermined change threshold, and/or the like.
[0096] If, at block 714, process 700 determines that the machine learning model is not to continue being trained (“no” at block 714), process 700 can end at 716. Conversely, if, at block 714, process 700 determines that the machine learning model is to continue being trained (“yes” at block 714), process 700 can loop back to 704 and can loop through blocks 704-714 with a different training sample.
[0097] In some implementations, an augmented training set (e.g., as described above in connection with Figures 4A, 4B, 5A, and 5B) may be used in connection with a machine learning model that utilizes a loss function that incorporates a degree of reverberation of a predicted clean audio signal, as described above in connection with Figure 7. In some implementations, the machine learning model may have an architecture that incorporates a CNN and a GRU in parallel, as shown in and described above in connection with Figure 6. By combining an augmented training set that includes training samples generated using synthesized AIRs with a machine learning model that utilizes a reverberation metric in a loss function that is optimized, and which may optionally have an architecture that utilizes both a CNN and a GRU, the machine learning model may be able to be efficiently trained (e.g., in a manner that minimizes computational resources) while achieving both a high degree of accuracy in a predicted dereverberated audio signal and a low degree of reverberation in the predicted dereverberated audio signal. Such a system may be particularly useful for dereverberation of real-time audio signals, which may require training on an expansive training set and a low-latency machine learning model architecture. Figure 8 shows a schematic diagram of an example system 800 that utilizes an augmented training set in connection with a machine learning model that utilizes a loss function that incorporates a degree of reverberation metric.
[0098] As illustrated, system 800 includes a training set creation component 802. Training set creation component 802 may generate an augmented training set that may be used by a machine learning model for dereverberating audio signals. In some implementations, training set component 802 may be implemented, for example, on a device that generates and/or stores an augmented training set. Training set creation component 802 may retrieve measured AIRs from an AIR database 806. Training set creation component 802 may then generate synthesized AIRs based on the measured AIRs retrieved from AIR database 806. More detailed techniques for generating synthesized AIRs are shown in and described above in connection with Figures 4A, 4B, and 5A. Training set creation component 802 can retrieve clean audio signals from clean audio signals database 804. Training set creation component 802 can then generate an augmented training set 808 based on the measured AIRs, the synthesized AIRs, and the clean audio signals. More detailed techniques for generating an augmented training set are shown in and described above in connection with Figure 5B. Augmented training set 808 may include multiple (e.g., one hundred, one thousand, ten thousand, or the like) training samples, with each training sample being a pair of a clean audio signal (e.g., retrieved from clean audio signal database 804) and a corresponding reverberated audio signal generated by training set creation component 802 based on a single AIR (either a measured AIR or a synthesized AIR).
[0099] Augmented training set 808 may then be used to train a machine learning model 810a. In some implementations, machine learning model 810a may have an architecture that includes a CNN and a recurrent element (e.g., a GRU, an LSTM network, an Elman RNN, or the like) in parallel. In particular, the CNN may generate an output based on outputs of layers of the CNN as well as an output of the recurrent element. An example of such an architecture is shown in and described above in connection with Figure 6. Machine learning model 810a may include a prediction component 812a and a reverberation determination component 814. Prediction component 812a may generate, for a reverberated audio signal obtained from augmented training set 808, a predicted dereverberated audio signal. Examples for generating the predicted dereverberated audio signal are described above in more detail in connection with Figures 2, 3, and 7. Reverberation determination component 814 may determine a degree of reverberation in the predicted dereverberated audio signal. For example, the degree of reverberation may be based on a speech-to-reverberation modulation energy, as described above in connection with block 708 of Figure 7. The degree of reverberation may be used to update weights associated with prediction component 812a. For example, the degree of reverberation may be included in a loss function that is minimized or optimized to update weights associated with prediction component 812a, as shown in and described above in connection with blocks 710 and 712 of Figure 7.
[0100] After training, trained machine learning model 810b may utilize trained prediction component 812b (e.g., corresponding to finalized weights) to generate dereverberated audio signals. For example, trained machine learning model 810b may take, as an input, a reverberated audio signal 814, and may generate, as an output, a dereverberated audio signal 816. It should be noted that trained machine learning model 810b may have the same architecture as machine learning model 810a, but may not determine a degree of reverberation at inference time.
[0101] Figure 9 is a block diagram that shows examples of components of an apparatus capable of implementing various aspects of this disclosure. As with other figures provided herein, the types and numbers of elements shown in Figure 9 are merely provided by way of example. Other implementations may include more, fewer and/or different types and numbers of elements. According to some examples, the apparatus 900 may be configured for performing at least some of the methods disclosed herein. In some implementations, the apparatus 900 may be, or may include, a television, one or more components of an audio system, a mobile device (such as a cellular telephone), a laptop computer, a tablet device, a smart speaker, or another type of device.
[0102] According to some alternative implementations the apparatus 900 may be, or may include, a server. In some such examples, the apparatus 900 may be, or may include, an encoder. Accordingly, in some instances the apparatus 900 may be a device that is configured for use within an audio environment, such as a home audio environment, whereas in other instances the apparatus 900 may be a device that is configured for use in “the cloud,” e.g., a server.
[0103] In this example, the apparatus 900 includes an interface system 905 and a control system 910. The interface system 905 may, in some implementations, be configured for communication with one or more other devices of an audio environment. The audio environment may, in some examples, be a home audio environment. In other examples, the audio environment may be another type of environment, such as an office environment, an automobile environment, a train environment, a street or sidewalk environment, a park environment, etc. The interface system 905 may, in some implementations, be configured for exchanging control information and associated data with audio devices of the audio environment. The control information and associated data may, in some examples, pertain to one or more software applications that the apparatus 900 is executing.
[0104] The interface system 905 may, in some implementations, be configured for receiving, or for providing, a content stream. The content stream may include audio data. The audio data may include, but may not be limited to, audio signals. In some instances, the audio data may include spatial data, such as channel data and/or spatial metadata. In some examples, the content stream may include video data and audio data corresponding to the video data. [0105] The interface system 905 may include one or more network interfaces and/or one or more external device interfaces (such as one or more universal serial bus (USB) interfaces). According to some implementations, the interface system 905 may include one or more wireless interfaces. The interface system 905 may include one or more devices for implementing a user interface, such as one or more microphones, one or more speakers, a display system, a touch sensor system and/or a gesture sensor system. In some examples, the interface system 905 may include one or more interfaces between the control system 910 and a memory system, such as the optional memory system 915 shown in Figure 9. However, the control system 910 may include a memory system in some instances. The interface system 905 may, in some implementations, be configured for receiving input from one or more microphones in an environment.
[0106] The control system 910 may, for example, include a general purpose single- or multi chip processor, a digital signal processor (DSP), an application specific integrated circuit (ASIC), a field programmable gate array (FPGA) or other programmable logic device, discrete gate or transistor logic, and/or discrete hardware components.
[0107] In some implementations, the control system 910 may reside in more than one device. For example, in some implementations a portion of the control system 910 may reside in a device within one of the environments depicted herein and another portion of the control system 910 may reside in a device that is outside the environment, such as a server, a mobile device (e.g., a smartphone or a tablet computer), etc. In other examples, a portion of the control system 910 may reside in a device within one environment and another portion of the control system 910 may reside in one or more other devices of the environment. For example, a portion of the control system 910 may reside in a device that is implementing a cloud-based service, such as a server, and another portion of the control system 910 may reside in another device that is implementing the cloud- based service, such as another server, a memory device, etc. The interface system 905 also may, in some examples, reside in more than one device.
[0108] In some implementations, the control system 910 may be configured for performing, at least in part, the methods disclosed herein. According to some examples, the control system 910 may be configured for implementing methods of dereverberating audio signals, training a machine learning model that performs dereverberation of audio signals, generating a training set for a machine learning model that performs dereverberation of audio signals, generating synthesized AIRs for inclusion in a training set, or the like. [0109] Some or all of the methods described herein may be performed by one or more devices according to instructions (e.g., software) stored on one or more non-transitory media. Such non- transitory media may include memory devices such as those described herein, including but not limited to random access memory (RAM) devices, read-only memory (ROM) devices, etc. The one or more non-transitory media may, for example, reside in the optional memory system 915 shown in Figure 9 and/or in the control system 910. Accordingly, various innovative aspects of the subject matter described in this disclosure can be implemented in one or more non-transitory media having software stored thereon. The software may, for example, include instructions for dereverberating audio signals using a trained machine learning model, training a machine learning model that performs dereverberation of audio signals, generating one or more synthesized AIRs, generating a training set for training a machine learning model that performs dereverberation of audio signals, etc. The software may, for example, be executable by one or more components of a control system such as the control system 910 of Figure 9.
[0110] In some examples, the apparatus 900 may include the optional microphone system 920 shown in Figure 9. The optional microphone system 920 may include one or more microphones. In some implementations, one or more of the microphones may be part of, or associated with, another device, such as a speaker of the speaker system, a smart audio device, etc. In some examples, the apparatus 900 may not include a microphone system 920. However, in some such implementations the apparatus 900 may nonetheless be configured to receive microphone data for one or more microphones in an audio environment via the interface system 910. In some such implementations, a cloud-based implementation of the apparatus 900 may be configured to receive microphone data, or a noise metric corresponding at least in part to the microphone data, from one or more microphones in an audio environment via the interface system 910.
[0111] According to some implementations, the apparatus 900 may include the optional loudspeaker system 925 shown in Figure 9. The optional loudspeaker system 925 may include one or more loudspeakers, which also may be referred to herein as “speakers” or, more generally, as “audio reproduction transducers.” In some examples (e.g., cloud-based implementations), the apparatus 900 may not include a loudspeaker system 925. In some implementations, the apparatus 900 may include headphones. Headphones may be connected or coupled to the apparatus 900 via a headphone jack or via a wireless connection (e.g., BLUETOOTH). [0112] Some aspects of present disclosure include a system or device configured (e.g., programmed) to perform one or more examples of the disclosed methods, and a tangible computer readable medium (e.g., a disc) which stores code for implementing one or more examples of the disclosed methods or steps thereof. For example, some disclosed systems can be or include a programmable general purpose processor, digital signal processor, or microprocessor, programmed with software or firmware and/or otherwise configured to perform any of a variety of operations on data, including an embodiment of disclosed methods or steps thereof. Such a general purpose processor may be or include a computer system including an input device, a memory, and a processing subsystem that is programmed (and/or otherwise configured) to perform one or more examples of the disclosed methods (or steps thereof) in response to data asserted thereto.
[0113] Some embodiments may be implemented as a configurable (e.g., programmable) digital signal processor (DSP) that is configured (e.g., programmed and otherwise configured) to perform required processing on audio signal(s), including performance of one or more examples of the disclosed methods. Alternatively, embodiments of the disclosed systems (or elements thereof) may be implemented as a general purpose processor (e.g., a personal computer (PC) or other computer system or microprocessor, which may include an input device and a memory) which is programmed with software or firmware and/or otherwise configured to perform any of a variety of operations including one or more examples of the disclosed methods. Alternatively, elements of some embodiments of the inventive system are implemented as a general purpose processor or DSP configured (e.g., programmed) to perform one or more examples of the disclosed methods, and the system also includes other elements (e.g., one or more loudspeakers and/or one or more microphones). A general purpose processor configured to perform one or more examples of the disclosed methods may be coupled to an input device (e.g., a mouse and/or a keyboard), a memory, and a display device.
[0114] Another aspect of present disclosure is a computer readable medium (for example, a disc or other tangible storage medium) which stores code for performing (e.g., coder executable to perform) one or more examples of the disclosed methods or steps thereof.
[0115] While specific embodiments of the present disclosure and applications of the disclosure have been described herein, it will be apparent to those of ordinary skill in the art that many variations on the embodiments and applications described herein are possible without departing from the scope of the disclosure described and claimed herein. It should be understood that while certain forms of the disclosure have been shown and described, the disclosure is not to be limited to the specific embodiments described and shown or the specific methods described.

Claims

1. A method for dereverberating audio signals, the method comprising: obtaining, by a control system a real acoustic impulse response (AIR); identifying, by the control system, a first portion of the real AIR that corresponds to early reflections of a direct sound and a second portion of the real AIR that corresponds to late reflections of the direct sound; generating, by the control system, one or more synthesized AIRs by modifying the first portion of the real AIR and/or the second portion of the real AIR; and using, by the control system, the real AIR and the one or more synthesized AIRs to generate a plurality of training samples, each training sample comprising an input audio signal and a reverberated audio signal, wherein the reverberated audio signal is generated based at least in part on the input audio signal and one of the real AIR or one of the one or more synthesized AIRs, wherein the plurality of training samples are used to train a machine learning model that takes, as an input, a test audio signal with reverberation and generates, as an output, a dereverberated audio signal.
2. The method of claim 1, wherein identifying the first portion of the real AIR that corresponds to early reflections and the second portion of the real AIR that corresponds to late reflections comprises selecting a random time value within a predetermined range, wherein the first portion comprises a portion of the real AIR prior to the random time value, and wherein the second portion comprises a portion of the real AIR after the random time value.
3. The method of claim 2, wherein the predetermined range is from about 20 milliseconds to about 80 milliseconds.
4. The method of any one of claims 1 - 3, wherein modifying the first portion of the real AIR comprises randomizing a time point of a response included in the first portion of the real AIR.
5. The method of any one of claims 1 - 4, wherein modifying the second portion of the real AIR comprises truncating the second portion of the real AIR after a duration of time randomly selected from a predetermined range of late reflection durations.
6. The method of any one of claims 1 - 5, wherein modifying the second portion of the real AIR comprises modifying amplitudes of one or more responses included in the second portion of the real AIR.
7. The method of claim 6, wherein modifying the amplitudes of the one or more responses included in the second portion of the real AIR comprises: determining a target attenuation function associated with the second portion of the real AIR; and modifying the amplitudes of the one or more responses included in the second portion of the real AIR in accordance with the target attenuation function.
8. The method of any one of claims 1 - 7, wherein the reverberated audio signal is generated by convolving the input audio signal with the one of the real AIR or the one of the one or more synthesized AIRs.
9. The method of any one of claims 1 - 8, further comprising adding noise to a convolution of the input audio signal with the one of the real AIR or the one of the one or more synthesized AIRs to generate the reverberated audio signal.
10. The method of any one of claims 1 - 9, further comprising generating additional synthesized AIRs by: identifying an updated first portion of the real AIR and an updated second portion of the real AIR; and modifying the updated first portion of the real AIR and/or the updated second portion of the real AIR.
11. The method of any one of claims 1 - 10, further comprising providing the plurality of training samples to the machine learning model to generate a trained machine learning model that takes, as the input, the test audio signal with reverberation and generates, as the output, the dereverberated audio signal.
12. The method of claim 11, wherein the test audio signal is a live-captured audio signal.
13. The method of any one of claims 1 - 12, wherein the real AIR is a measured AIR measured in a physical room.
14. The method of any one of claims 1 - 13, wherein the real AIR is generated using a room acoustics model.
15. The method of any one of claims 1 - 14, wherein the input audio signal is associated with a particular audio content type.
16. The method of claim 15, wherein the particular audio content type comprises far- field noise.
17. The method of any one of claims 15 or 16, wherein the particular audio content type comprises audio content captured in an indoor environment.
18. The method of any one of claims 15 - 17, further comprising obtaining a training set of a plurality of input audio signals each associated with the particular audio content type prior to generating the plurality of training samples.
19. An apparatus configured for implementing the method of any one of claims 1-18.
20. One or more non-transitory media having software stored thereon, the software including instructions for controlling one or more devices to perform the method of any one of claims 1-18.
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